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Transcript
Advance Program
Sunday, October 12, 2014
Sunday Session
12:00 PM - 3:30 PM
Session Chair: Lukas Chrostowski, University of British Columbia, Canada
Short Course: Introduction to Silicon Photonics Device Design and Fabrication Workshop
This short course teaches participants how to design passive silicon photonic devices using analytic and
advanced numerical techniques. Participant designs will be fabricated by a state-of-the-art rapidprototyping 100 keV electron-beam lithography facility (University of Washington, USA). All designs
will be tested using an automated optical probe station and the data provided to the
participants. Participants will then analyze their experimental data.
4:30 PM - 6:30 PM
Session Chair: Martin Dawson, Institute of Photonics, University of Strathclyde, Scotland
“Hot Papers” & “Meet the Editors”
This new event will offer the opportunity to meet and hear from Carmen Menoni (Editor of IEEE
Photonics Journal) and Seb Savory (Editor of IEEE Photonics Technology Letters) about the mission and
focus of their journals, and will involve presentations, by the respective authors, of recent ‘highlight’
papers from these journals, as selected by the journal editorial boards.
Session followed by refreshments
6:30 PM - 7:30 PM
Session Chair: Alexandra Boltasheva, Purdue University, USA
Panel on Metamaterials
At a time when new materials, devices, applications and regimes of operation for Metamaterials are
emerging rapidly, this panel discussion will allow the community to take stock of where the field is
heading and discuss the challenges and opportunities ahead. This panel is organized by Alexandra
Boltasseva (Purdue University, USA).
Panelists:
Alexandra Boltasheva (Moderator) Purdue University, USA
Andrea Alu, University of Texas at Austin, USA
Nader Engheta, University of Pennsylvania, USA
Nanfang Yu, Columbia University, USA
Zubin Jacob, University of Alberta, Canada
Monday, October 13, 2014
8:30 AM - 10:30 AM
Session MA1: Advances in Biophotonics
Session Chair: Audrey Ellerbee, Stanford University, USA
MA1.1 8:30 AM - 9:00 AM (Invited)
Rethinking Microscopy, C. Yang, California Institute of Technology, CA, USA
I will discuss my group’s recent work on rethinking microscopy from the ground up. I will report on a
self-imaging petri dish technology (ePetri) which is capable of streaming microscopy-level live cell
culture images directly out of the incubator.
MA1.2 9:00 AM - 9:30 AM (Invited)
Vesicle Photonics in Biology with a Focus on Single Cell Analysis, A. E. Vasdekis, Pacific Northwest
National Laboratory, Richland, WA, USA, E. Scott, J. A. Hubbell and D. Psaltis, Ecole Polytechnique
Federale de Lausanne, Lausanne, Switzerland
Vesicle Photonics will be introduced, focusing on the optical stimulation and imaging of single cells.
Applications in drug delivery will be detailed, as well as ongoing work (PNNL) on the synthesis of
advanced bio-fuels.
MA1.3 9:30 AM - 10:00 AM (Invited)
Simultaneous spatial and temporal focusing for tissue ablation, J. Squier and C. Durfee, Colorado
School of Mines, Golden, CO, USA
Simultaneous spatial and temporal focusing (SSTF) effectively inhibits nonlinear processes that
traditionally reduce the precision with which a low numerical aperture beam can ablate or modify
materials. A novel SSTF compression architecture and characterization techniques are described.
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session MB1: Novel LEDs
Session Chair: Peyman Servati, University of British Columbia, Vancouver BC
MB1.1
8:30 AM - 9:00 AM (Invited)
InGaN-based Nanocoumn Emitters Suitable for Display Applications, K. Kishino, Sophia University
and Sophia Nanotechnology Research Center, A. Yanagihara and S. Ishizawa, Sophia University, Japan
Three primary colors LEDs with a high directional radiation beam profile will be effectively utilized for
projection type LED displays.
MB1.2
9:00 AM - 9:15 AM
Extending quantum efficiency roll-over threshold with compositionally graded InGaN/GaN LED,
P. Mishra, T. Ng, B. Janjua, C. Shen, Photonics Lab, Thuwal, Saudi Arabia, J. Eid, Solar and Alternative
Energy Engineering Center, Thuwal, Saudi Arabia, A. Alyamani, M. El-Desouki, King Abdulaziz City for
Science and Technology, Riyadh, Saudi Arabia and B. Ooi, Photonics Lab, Thuwal, Saudi Arabia
We report a significant improvement in the electrical characteristic of compositionally graded
InGaN/GaN multiple-quantum-well (MQWs) micro-LED. The efficiency droop in this device occurred at
~20 times higher injection levels (~275 A/cm2) compared to a conventional step-MQWs micro-LED (~14
A/cm2).
MB1.3
9:15 AM - 9:30 AM
Phosphor modeling based on reabsorption of Stokes shifted light, S. Jeon, Korea Photonics
Technology Institute, Gwangju, Korea, J. Noh, K. Kim, W. Kim, C. Yun, S. Song and J. Kim, KOPTI,
Gwangju, Korea
When the emission spectrum of the powder state is adopted in an optical simulation, the simulated optical
properties show a remarkable discrepancy from those of the fabricated LED package. We suggest that the
discrepancy originates from the absorption of Stokes shifted light by a phosphor.
MB1.4
9:30 AM – 10:00 AM (Invited)
Direct Emitting LEDs for Displays, C. Wetzel, Rensselaer Polytechnic Institute, USA
Progress and research needs are emphasized for energy efficient display illumination by means of groupIII nitride based direct emitting LEDs, bypassing the lossy phosphor conversion.
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session MC1: Waveguides and Devices for Optical Interconnects I
Session Chair: Ozan Yilmaz
MC1.1 8:30 AM - 8:45 AM
Adaptive Coupling Approach for Single Mode VCSELs with Polymer Waveguides, E. Bosman,
CMST: Ghent University & IMEC, Gent, Belgium, A. Elmogi, CMST : Ghent University and IMEC,
Gent, Belgium, S. Wiegersma, TNO, Eindhoven, The Netherlands, H. van den Berg, TNO, Delft, The
Netherlands, M. Ortsiefer, A. Daly, VERTILAS GmbH, Garching, Germany and G. Van Steenberge,
CMST: Ghent University and IMEC, Gent, Belgium
A novel scalable coupling approach for single mode VCSELs and planar optical waveguides is presented.
The coupling is based on the embedding of the VCSELs inside the substrate and the adaptive fabrication
of waveguides on top, realizing 1 um alignment accuracy.
MC1.2 8:45 AM - 9:15 AM (Invited)
Polymer Waveguide Based Electro-Optical Assembly Technology for Computing Applications, R.
Dangel, F. Horst, D. Jubin, A. La Porta, N. Meier, J. Weiss and B. J. Offrein, IBM Research, Switzerland
We extend our state-of-the-art multi-mode polymer waveguide technology to single-mode operation at a
wavelength of 1300 nm and demonstrate the potential of this single-mode optical PCB technology for the
assembly of silicon photonics chips.
MC1.3 9:15 AM - 9:30 AM
45-degree Mirrors on Graded-Index Core Polymer Optical Waveguides for Low-Loss Light
Coupling, Y. Morimoto, Keio University, Yokohama, Japan, R. Kinoshita, A. Takahashi and T. Ishigure,
Keio University, Japan
We demonstrate that graded-index (GI) profile in square-core waveguides improve the loss at 45-degree
mirrors on its ends over the SI-core waveguides. We also fabricate and characterize the mirror on GI
“circular”-core waveguides.
MC1.4 9:30 AM - 9:45 AM
Photomask Free Fabrication of Single-Mode Polymer Optical Waveguide Using the Mosquito
Method, S. Yoshida, Keio university, Yokohama, Japan
We demonstrate a photomask-free fabrication for single-mode polymer optical waveguides using the
Mosquito method. In fabricating the waveguides, an inorganic-organic hybrid resin is applied to decrease
the carbon-hydrogen absorption loss at 1550-nm wavelength.
MC1.5 9:45 AM - 10:00 AM
An Approach to Optimize the Diffusion Process for Graded Index Waveguides Fabrication in Thin
Glass Sheets, D. Zhang, T. Kuehler, J. H. Stosch and E. Griese, Institute of Theoretical Electrical
Engineering and Photonics, Siegen, Germany
A back-propagation neural network was introduced to model and optimize the Ag+-Na+ ion-exchange
process for graded index waveguide fabrication in thin glass sheets. After optimization, the network
trained with numerical experiment results showed very good generalization ability.
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session MD1: PON and Data Networks
Session Chair: Ming Xia, Ericson Inc., USA
MD1.1 8:30 AM - 9:00 AM (Invited)
Optical Interconnection Networks for Data Centers, O. Liboiron-Ladouceur, Dept. of Electrical. &
Computer Eng., McGill University, Montreal, QC,, Canada
Optical networks implementation exploiting the energy-proportional concept within the switches and in
the signal conversion interface will be discussed, as well as optical networks implemented onto a single
chip leading to new opportunities.
MD1.2 9:00 AM - 9:15 AM
WDM-IDMA Solution for NG-PON2 Enabled by Coherent Technology and Colorless ONUs, E. A.
El-Fiky, Z. A. El-Sahn, Electrical Engineering Department, Faculty of Engineering, Alexandria,
Alexandria, Egypt and H. Shalaby, Department of Electronics and Communications Engineering, EgyptJapan, Alexandria, Egypt
We propose a novel hybrid solution for NGPON2 combining wavelength-division multiplexing (WDM)
and interleave-division multiple-access (IDMA). Results demonstrate the uplink transmission supporting
more than 90 colorless ONUs at 1.25 Gb/s each over 100 km reach.
MD1.3 9:15 AM - 9:30 AM
Performance Upgrade of Low-Bandwidth RSOA Devices Using 4-PAM and Pre-Equalization , C.
Stamatiadis, Technische Universitaet Berlin, Joint Lab Silicon Photonics, Berlin, AE, Germany, Y.
Yoshida, Dept. of Electrical and Information Engineering, OSAKA university, OSAKA, Japan, R.
Matsumoto, Dept. of Electrical and Information Engineering, Osaka University, Osaka, Japan, A. Agata,
KDDI R&D Laboratories Inc., Osaka, Japan, A. Maruta and K. Kitayama, Dept. of Electrical and
Information Engineering, Osaka University, Osaka, Japan
We present 4-PAM external modulation up to 10Gbit/s using a RSOA with a 3-dB bandwidth of 1.2GHz.
By applying pre-equalization we demonstrate 10km 4-PAM transmission at 8Gbit/s with bit-error-rate
below the FEC limit.
MD1.4 9:30 AM - 10:00 AM (Invited)
Optical Physical-Layer Network Coding – Another Dimension to Increase Network Capacity?, L.
Chen, The Chinese University of Hong Kong, China
Network coding is a revolutionary technique that can enhance network throughput and protection. This
presentation introduces optical physical-layer network coding (OPNC), focusing on “common-channel”
OPNC that can fully utilize network resources. OCIS codes: (060.2330) Fiber optics communications;
(060.4259) Networks, packet-switched
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session ME1: VCSEL 1
Session Chair: TBD
ME1.1
8:30 AM - 9:00 AM (Invited)
Design and Reliability of High speed VCSELs with Emphasis on 850 nm, J. Guenter, Finisar Corp,
USA
ME1.2
9:00 AM - 9:15 AM
VCSELs for Computer Interconnects, D. Bimberg, H. Li, P. Moser, P. Wolf, G. Larisch and J. A. Lott,
Technische Universität Berlin, Germany
Temperature-stable, energy-efficient, and error-free data transmission with oxide-confined 980 nm
VCSELs is obtained for bit rates from 25 to over 40 Gb/s across the broad temperature range 25 to 85 °C.
The VCSELs are well-suited for board-to-board, chip-to-chip, and on-chip optical interconnects for
computer communications.
ME1.3
9:15 AM - 9:30 AM
240 Gbit/s VCSEL Array for Multicore Fiber Interconnects, P. Westbergh, J. S. Gustavsson and A.
Larsson, MC2 - Photonics Laboratory, Gothenburg, Sweden
We report on the performance of a 6-channel 850 nm VCSEL array intended for multicore fiber
interconnects and demonstrate individual channels capable of 40 Gbit/s error-free transmission for an
aggregate capacity of 240 Gbit/s.
ME1.4
9:30 AM - 9:45 AM
Modulation Bandwidth Enhancement via Resonance Detuning in Coherently Coupled Vertical
Cavity Laser Arrays, S. T. Fryslie, University of Illinois at Urbana-Champaign, Champaign, IL, USA,
M. T. Johnson, United States Air Force, Baltimore, MD, USA, M. Tan, Intel Corp., Hillsboro, OR, USA,
D. F. Siriani, MIT Lincoln Laboratories, Lexington, MA 02420, Lexington, MA, USA and K. D.
Choquette, University of Illinois at Urbana-Champaign, Champaign, IL, USA
We show significant improvement of modulation bandwidth from 1x2 vertical cavity surface emitting
laser arrays that are coherently coupled as compared to incoherent operation. 25 GHz small signal
bandwidth is obtained with single mode operation and increased output power.
ME1.5
9:45 AM - 10:00 AM
Polarization Switching and Bistability in a 1300 nm spin-VCSEL Subject to Circularly Polarized
Optical Injection, S. S. Alharthi, A. Hurtado, University of Essex, Colchester, UK, V. Korpijärvi,
Tampere University of technology, Tampere, Finland, M. Gunia, Tampere University of Technology,
Tampere, Finland, I. Henning and M. Adams, University of Essex, Colchester, UK
We report the first experimental observation of different forms of polarization switching and bistability in
an optically injected 1300nm dilute nitride spin-VCSEL and for both (right- and left-) circularly polarized
modes of the device.
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session MF1: Frequency Combs and Non Linear Effects in Microresonators
Session Chair: Alexey Maslov, University of Nizhny Novgorod, Russia
MF1.1
8:30 AM - 9:00 AM (Invited)
Kerr Optical Frequency Combs for Ultra-Stable Microwave and Lightwave Signal Generation, Y.
Chembo, FEMTO-ST Institute, France
MF1.2
9:00 AM - 9:15 AM
Broadband Mode-Locked Kerr Combs Based on Soft Excitation of Microresonator Dark Solitons,
X. Xue, Y. Xuan, Y. Liu, P. Wang, S. Chen, J. Wang, D. E. Leaird, M. Qi and A. M. Weiner, Purdue
University, USA
Mode-interaction-aided soft excitation of dark solitons in normal dispersion nonlinear microresonators is
proved both experimentally and in simulation for the first time, resulting in dark pulse mode-locked
broadband Kerr combs.
MF1.3
9:15 AM - 9:30 AM
Control of Kerr Optical Frequency Comb Generation with Temperature Dependent Group
Velocity Dispersion, A. Matsko, W. Liang, V. Ilchenko, A. Savchenkov, J. Byrd, D. Seidel and L.
Maleki, OEwaves Inc, Pasadena, USA
Kerr frequency comb generation in a MgF2 microresonator depends on the resonator temperature. This
effect occurs as a consequence of change of local group velocity dispersion of the resonator spectrum
resulting from linear interaction among resonator modes.
MF1.4
9:30 AM - 9:45 AM
All-Optical Switching in a GaAs Microdisk Resonator, Y. Lin, M. Mao, Y. Lin, H. Lin, C. Lin and L.
A. Wang, National Taiwan University, Taiwan, Republic of China
We demonstrated high-speed all-optical switching in a GaAs microdisk resonator using the tapered fiber
pump probe technique. The optical transmission of the resonator was modulated with a time response of
43 ps.
MF1.5
9:45 AM - 10:00 AM
Dynamical Investigation of Kerr-Type Coupled Ring Resonators, Y. Eksioglu, Brno University of
Technology, Brno, Czech Republic
The dynamics of nonlinear resonant structures consisting of two coupled ring resonators were
investigated for non-instantaneous Kerr response. We demonstrated transitions from stable states to selfpulsing and chaotic states.
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session MG1: Visible Light & Other Systems
Session Chair: Ian White, Cambridge University, UK
MG1.1 8:30 AM - 8:45 AM
Visible Light Communications: Improving Data Rate, Link Margin and Field of View, D. O'Brien,
S. Collins, H. Chun, G. Faulkner, S. Rajbhandari, A. Watt, University of Oxford, Oxford, UK, P.
Manousiadis, D. A. Vithanage, G. A. Turnbull, I. D. Samuel, University of St Andrews, St Andrews, UK,
R. Henderson, K. Cameron, A. V. Jalajakumari, D. Tsonev, S. Videv, H. Haas, University of Edinburgh,
Edinburgh, UK, E. Xie, E. Gu, J. J. McKendry and M. D. Dawson, University of Strathclyde, Glasgow,
UK
A consortium of UK universities (Strathclyde, Oxford, Cambridge, St.Andrews, Edinburgh) has been
investigating the use of micro-LEDs for VLC. This paper details improvements to transmitter and
receiver that can increase link margin, field of view and data rate.
MG1.2 8:45 AM - 9:00 AM
Singular Layer Transmission for Continuous-Variable Quantum Key Distribution, L. Gyongyosi,
Budapest University of Technology, Hungarian Academy of Sciences, Hungary and S. Imre, Budapest
University of Technology, Hungary
We develop a singular layer transmission model for continuous-variable quantum key distribution
(CVQKD). We show that the singular layer assistance provides improved secret key rates for CVQKD,
particularly in crucial low signal-to-noise ratio regimes.
MG1.3 9:00 AM - 9:15 AM
Demonstration of a Bi-directional Visible Light Communication with an Overall Sum-rate of 110
Mb/s using LEDs as Emitter and Detector, H. Chun, Oxford University, Oxford, UK, S. Rajbhandari,
G. Faulkner, Department of Engineering Science, University of Oxford, Oxford, UK, D. Tsonev, H. Haas,
Institute for Digital Communications, University of Edinburgh, Edinburgh, UK and D. O’Brien,
Department of Engineering Science, University of Oxford, Oxford, UK
This paper investigates the feasibility of moderate data rate visible light communication using commercial
RGB-LEDs as both emitters and detectors. Data rates of 155 Mb/s (uni-directional) and 110 Mb/s
(aggregate bi-directional) were demonstrated.
MG1.4 9:15 AM - 9:30 AM
Performance of Time-Bandwidth Engineering Systems, J. Chan, M. Asghari and B. Jalali, UCLA,
Photonics Lab., Los Angeles, CA, USA
Recently introduced Stretched Modulation Distribution is used to study tolerance to non-idealities in time
bandwidth engineering systems that employ nonlinear phase operations. In particular, the performance in
far field and near field regimes is determined by group delay ripples at lower and higher frequencies,
respectively.
9:30 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session MH1: Nanophotonics Tutorial
Session Chair: Ertugrul Cubukcu, University of Pennsylvania, USA
MH1.1 8:30 AM – 10:00 AM (Tutorial)
Optical Nanoantennas, N. Engheta, University of Pennsylvania, Philadelphia, USA
Optical nanoantennas have become an important part of nano-optics, nanophotonics, and micro- and
nanoscale light-matter interaction. In this tutorial, I present an overview of some of the fundamental
concepts and recent developments in this area.
10:00 AM - 10:30 AM Coffee Break
10:30 AM - 1:30 PM
Session MA2: Bioimaging and Tomography
Session Chair: Changhuei Yang, California Institute of Technology, USA
MA2.1 10:30 AM - 11:00 AM (Invited)
Optical Coherence Tomography: Technology and Applications, A. Ellerbee, Stanford University,
USA
Optical coherence tomography (OCT) is a competitor to established techniques for imaging tissue
microstructure and small animals. We describe work at Stanford towards the development of new OCT
system schemes, algorithms, phantoms and clinical applications.
MA2.2 11:00 AM - 11:30 AM (Invited)
Optical Coherence in all the Right (and Wrong) Places: Using and Designing Coherence for
Biomedical Imaging, M. A. Choma, Yale University, USA
The spatial and temporal coherence of optical fields are basic properties that have been successfully
exploited in biomedical optics. I will discuss our biomedical use of optical coherence tomography and our
work in the targeted design of desirable spatial coherence properties in light sources.
MA2.3 11:30 AM - 11:45 AM
A Novel Electro-Optically Tuned Optical Coherence Tomography Technique for Dental Imaging,
V. Damodaran, N. J. Vasa and S. U, Indian Institute of Technology Madras, India
An optical coherence tomography (OCT) system for imaging dental caries is studied. A potassium
tantalate niobate crystal based electro-optic OCT system with an optical-path scanning range of 441.9
micrometers under 1 kV is proposed.
MA2.4 11:45 AM - 12:00 PM
Low Aberration KTa1-xNbxO3 Varifocal Lens for Visible Wavelength Range Applications, J.
Miyazu, T. Imai and J. Kobayashi, NTT Photonics Laboratories, NTT Corporation, Japan
Varifocal lenses for visible wavelength range applications are fabricated using KTa1-xNbxO3 crystals.
The unexpected beam distortion caused by the aberration of the lenses is greatly reduced by suppressing
electron injection.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session MB2: Waveguides and Devices for Optical Interconnects II
Session Chair: Rena Huang, Teradiode Inc., USA
MB2.1
10:30 AM - 10:45 AM
LaC: Integrating Laser Control in a Photonic Interconnect, Y. Demir and N. Hardavellas,
Northwestern University, USA
Silicon photonics are an attractive technology for global interconnects in many-core processors. However,
they come with significant laser power consumption. Turning off underutilized portions of the
interconnect can save 62-92% of the laser power.
MB2.2 10:45 AM - 11:00 AM
Surface-normal photonic Crystal Membrane Reflectors with Integrated In-Plane Couplers for
Integrated Silicon Photonics, D. Zhao, A. S. Chadha, S. Liu, H. Yang, Y. Shuai, University of Texas at
Arlington, USA, Z. Ma, University of Wisconsin-Madison, USA and W. Zhou, University of Texas at
Arlington, USA
We report design and fabrication of photonic crystal (PC) Si membrane reflectors with integrated in-plane
couplers (Si MR-Coupler) based on Fano resonance effect. The measured results show the Si MRCoupler has a 99% reflection and > 0.22% in-plane coupling efficiency.
MB2.3
11:00 AM - 11:15 AM
Electro-optic Polymer Modulator with Low-driving Voltage and High-Bandwidth Toward HighRefractive Index Waveguide Plateform, S. Yokoyama, Kyushu University, Japan
We show our recent achievement of the electro-optic polymer waveguide modulator with a very small
half-wave-voltage (driving voltage) and 50 GHz bandwidth property. Furthermore, we use EO polymer
with the high-refractive index waveguide such as silicon nitride and titanium dioxide toward silicon
photonics application.
MB2.4
11:15 AM - 11:30 AM
Improvement in Crosstalk of 200-Port Bragg Reflector Waveguides Array-Based Wavelength
Selective Switch, X. Gu, Tokyo Institute of Technology, Japan, K. Suzuki, Y. Ikuma, NTT Photonics
Laboratories, Japan, A. Matsutani and F. Koyama, Tokyo Institute of Technology, Japan
We analyze and improve the crosstalk between adjacent output-ports in Bragg reflector waveguides arraybased wavelength selective switching. Crosstalk below -23 dB is obtained in a 200-port waveguide array
with a pitch of only 30 µm.
MB2.5
11:30 AM - 11:45 AM
Polarization Independent Optofluidic Nematic Liquid Crystal Channels, A. d'Alessandro, R.
Asquini, L. Martini, Sapienza University of Rome, Italy, R. Beccherelli, Consiglio Nazionale delle
Ricerche, Italy and G. Gilardi, University of Technology Eindhoven, The Netherlands
We present the fabrication and the characterization of waveguides made of a nematic liquid crystal
infiltrated in PDMS channels. The molecular orientation inside the waveguides allows only 0.3 dB
variation of light transmission versus polarization.
11:45 AM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session MC2: Designs for Integration
Session Chair: Yulia Akulova, JDSU, USA
MC2.1 10:30 AM - 11:00 AM (Invited)
Photonic Molecules for Optical Signal Processing, L. A. Barea, M. C. Souza, G. F. Rezende and N. C.
Frateschi, University of Campinas, Brazil
We demonstrate how CMOS compatible photonic molecules (PM) can break the fundamental
interdependence among quality factor (Q), channel spacing and size of microring resonators. Different
PM architectures are presented for efficient and compact optical signal processing.
MC2.2 11:00 AM - 11:15 AM
Bandpass Bragg Grating Transmission Filters and Optical Add-Drop Multiplexers on Silicon-onInsulator, J. Wang and L. R. Chen, McGill University, Canada
We demonstrate bandpass transmission filters and optical add-drop multiplexers on SOI based on
interferometric structures incorporating a pair of sidewall Bragg gratings.
MC2.3 11:15 AM - 11:30 AM
Side Lobe Suppression in Wavelength Characteristics of the Grating Loaded in a Mach-Zehnder
Interferometer Waveguide, Y. Hayama, Kanagawa Institute of Technology, Japan
We propose a silicon waveguide Mach-Zehnder in-terferometer with weighted grating structures for a
tunable add-drop filter. Theoretically and experimen-tally obtained wavelength characteristics with suppressed side lobes in the proposed device are reported.
MC2.4 11:30 AM - 11:45 AM
Inductively Coupled Plasmas (ICP) Etching of PZT Thin Films for Fabricating Optical Waveguide
with Photoresist/Aluminum Bilayer Masking, Z. Qi, G. Hu and Y. Cui, School of Electronic Science
and Engineering, Southeast University, China
PZT ridge waveguide morphology was studied by ICP etching. The waveguide morphology etched by
single electrode ICP was much better than that of the dual-electrode ICP under the optimal conditions.
MC2.5 11:45 AM - 12:15 PM (Invited)
Silicon Photonics for WDM Nodes in UC San Diego’s Data-Center Network, S. Mookherjea,
University of California, San Diego, Electrical and Computer Engineering
We present results from the recent collaboration between UC San Diego and Sandia National
Laboratories via CIAN-ERC, demonstrating some wavelength-division multiplexing functionality
implemented in the MORDIA circuit-switched ring network, including node-on-a-chip and multi-channel
spectral monitoring.
12:15 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session MD2: Optical Radio and Overlay Technologies
Session Chair: Anthony Kelly, University of Glasgow, UK
MD2.1 10:30 AM - 10:45 AM
An Effect of Detuning Frequency in DSP-Assisted Offset-Frequency-Spaced Two-Tone Optical
Coherent Detection for Radio-over-Fiber Signal, T. Kuri, T. Sakamoto and T. Kawanishi, National
Institute of Information and Communications Technology, Japan
A digital-signal-processing-assisted optical coherent detection of an uplink radio-over-fiber signal with a
two-tone local light, which is insensitive to laser phase fluctuation, is newly proposed and its phase
fluctuation cancellation effect is experimentally demonstrated.
MD2.2 10:45 AM - 11:00 AM
Experimental and Simulation Analysis of the W-band SC-FDMA Hybrid Optical-Wireless
Transmission, A. Dogadaev, X. Pang, DTU Fotonik, Kgs. Lyngby, Denmark, L. Deng, Huazhong
University of Science and Technology, China, S. Ruepp, L. Dittmann and H. L. Christiansen, DTU
Fotonik, Kgs. Denmark
We report on the experimental demonstration of the W-band hybrid optical-wireless SC-FDMA with 1.49
Gbit/s transmission over up to 2.3 m of air propagation. Provided simulation performance analysis proves
a potential to reach 12.1 Gbit/s.
MD2.3 11:00 AM - 11:30 AM (Invited)
Photonics Enabled Wireless Networks: Optical Wireless and Optical Backhaul, T. Nirmalathas, K.
Wang, Y. Yang and C. Lim, University of Melbourne, Parkville, Australia
Optical technologies can enable efficient backhaul for mobile networks and can provide direct wireless
transmission to support ultra-broadband connectivity. This paper examines the complimentary role of
optical networking and optical systems in broadband wireless access networks.
MD2.4 11:30 AM - 11:45 AM
Data Overlay in Optical Networks Through Level-Scalable Flexible Modulation and its Application
in Multicast Overlay for WDM-PON, G. Lu, NICT, Japan; Tokai University, Japan, T. Sakamoto and
T. Kawanishi, NICT, Japan
We propose an optical data overlay scheme through level-scalable flexible modulation. Using this
proposed scheme, Optical multicast overlay over point-to-point unicast in WDM-PON is experimentally
demonstrated by scaling up the modulation from QPSK to 16QAM at 10Gbaud.
MD2.5 11:45 AM - 12:00 PM
Modulation Format Conversion from BPSK to QPSK Using Delayed Interferometer and Pulse
Shaping Filter, M. Mihara, Y. Shinohara, H. Kishikawa, N. Goto, The University of Tokushima, Japan
and S. Yanagiya, The University of Tokushima, Japan
Previously we demonstrated an all-optical modulation format conversion from BPSK to QPSK without
employing band narrowing filter. In this report, we propose a complete conversion system with filtering
and the performance is numerically confirmed.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session ME2: VCSELs, Nanolasers and Microdisks
Session Chair: Dieter Bimberg, TU Berlin, Germany
ME2.1
10:30 AM - 11:00 AM (Invited)
Coherent Coupling in Vertical Cavity Laser Arrays, K. Choquette, University of Illinois at UrbanaChampaign, USA, M. T. Johnson, United States Air Force, USA, Z. Gao, B. Thompson, G. Ragunathan,
S. Fryslie, University of Illinois, USA, M. Tan, Intel Corporation, USA and D. Siriani, University of
Illinois, USA
We discuss the physics and applications of coherently coupled photonic crystal vertical cavity surface
emitting laser arrays. The optical phase between elements can be controlled using a novel temporal phase
shifting mechanism.
ME2.2
11:00 AM - 11:30 AM (Invited)
Room Temperature Plasmonic Nanolasers, T. W. Odom, Northwestern University, USA
This talk will describe how strongly coupled nanoparticle arrays can behave as an unconventional cavity
structure for plasmonic nanolasers. Room temperature, directional emission was achieved.
ME2.3
11:30 AM - 11:45 AM
Stokes Parameters and Hybridization of Optical Modes in Long-Wavelength vertical-Cavity
Surface-Emitting Lasers (VCSELs), N. Volet, B. Dwir, A. Sirbu, V. Iakovlev, A. Mereuta, EPFL,
Switzerland, A. Caliman, G. Suruceanu, BeamExpress S.A., Switzerland and E. Kapon, EPFL,
Switzerland
The polarization of the beam emitted from long-wavelength VCSELs is characterized with the Stokes
parameters. Stable optical modes are discovered, with a polarization that differs from the linear case.
Results are explained by hybridization of the VCSEL modes and a negative linewidth enhancement
factor.
ME2.4
11:45 AM - 12:00 PM
High-Q Current-Injection InAs Quantum-dot Microdisk Lasers Operating at Room Temperature,
C. Chu, Y. Li, C. Cheng and M. Mao, National Taiwan University, Taiwan, Republic of China
We report room-temperature operation of current-injection InAs quantum-dot microdisk lasers with
quality factor >23,000. The lasing wavelength is at 1136nm with threshold current of 0.39mA.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session MF2: Theory and Applications of Microresonators
Session Chair: Misha Sumetsky, Aston University, UK
MF2.1
10:30 AM - 11:00 AM (Invited)
The Use of Optical resonances in Energy and Thermal Applications, S. Fan, Stanford University,
USA
MF2.2
11:00 AM - 11:15 AM
Integrated Field-Programmable 2×2 Optical Switch on a Multilayer Platform, M. Sodagar, A. H.
Hosseinnia, A. A. Eftekhar and A. Adibi, Georgia Tech, USA
We demonstrate field-programmable 2×2 optical switch based on resonance elimination through
dielectric breakdown phenomenon on a high-quality multilayer platform (Si/SiO2/Si). Fabricated device
exhibits an on/off extinction ratio of more than 20 dB for both routes.
MF2.3
11:15 AM - 11:30 AM
Athermal Characteristics of TiO2-Clad Silicon Waveguides at 1.3µm, S. Feng, K. Shang, University
of California, USA, J. Bovington, R. Wu, K. Cheng, J. Bowers, University of California, USA and S. Yoo,
University of California, USA
We investigate athermal characteristics of silicon waveguides clad with TiO2. The measured ring
resonance wavelengths near 1.3 µm over 20-50°C exhibit second-order thermo-optical effects and
spectral dependency, implying second-order effects from TiO2 and Si combination.
MF2.4
11:30 AM - 11:45 AM
An Optical Delayline Based on Excitable Microrings, T. Van Vaerenbergh, M. Fiers, UGent-imec,
Belgium, J. Dambre and P. Bienstman, Ghent university, Belgium
We present in simulation a photonic neural circuit achieving a 200 ns spike delay, based on excitability in
microrings. This type of delayline paves the way towards fully integrated optical spiking neural networks.
MF2.5
11:45 AM - 12:00 PM
Practice and Theory in Silicon-on-Insulator Slot Waveguide, M. Salih, Research Assistant, Baghdad,
Iraq and X. Chen, University of Colorado Boulder, USA
In this paper, a phenomenological method for improving the accuracy of SoI slot waveguide modeling is
presented. By incorporating loss factor from experimental measurement into numerical model, agreement
between numerical and measurement results is achieved.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session MG2: Modulation & Detection I
Session Chair: Zhenning Tao, Fujitsu R&D Center, China
MG2.1 10:30 AM - 11:00 AM (Invited)
Optical Spectral Shaping and High Spectral Efficiency in Long Haul Systems, M. Mazurczyk, TE
SubCom, USA
Spectral shaping implemented with digital-to-analog converters is a powerful technique for increasing
spectral efficiency. We review both its background and experimental demonstrations including a record
single core result of 44.1 Tb/s over 9,100 km.
MG2.2 11:00 AM - 11:15 AM
Fiber Nonlinearity Mitigation in CO-OFDM Systems Using Dual Compensators, S. Hussin and R.
Noe, Optical Communication and High-Frequency Engineering, Germany
We simulate frequency domain dual compensators for nonlinear phase noise mitigation in a 1200 km 40
Gbps coherent optical OFDM transmission system with inline dispersion compensation. This technique
effectively compensates SPM induced by fiber nonlinearity.
MG2.3 11:15 AM - 11:30 AM
Optical Phase Noise Suppression in CO-OFDM System with Sub-Symbol Processing and Linear
Interpolation, X. Hong, South China Normal University, China, X. Hong, South China Normal
University, China, D. Wang, Huawei Technologies, China and S. He, South China Normal University,
China
Two optical phase noise suppression algorithms based on sub-symbol processing and linear interpolation
are proposed for CO-OFDM system. With increased temporal resolution and accuracy in phase
estimation, the new algorithms increase system’s laser linewidth tolerance significantly.
MG2.4 11:30 AM - 11:45 AM
ROADM Cascade Performance in DD Multi-band OFDM Metro Networks Employing Virtual
Carriers, J. Rosario, T. Alves and A. Cartaxo, Instituto de Telecomunicações, Portugal
A cascade of ROADMs in direct-detection multi-band (MB) OFDM metro networks employing virtual
carriers is analyzed numerically. Results indicate that, for a 3-band MB-OFDM network with 40 kmspans, 26 ROADMs can be traversed with BER<10^-3.
MG2.5 11:45 AM - 12:00 PM
Experimental Demonstration of an OFDM Receiver Based on a Silicon-Nanophotonic Discrete
Fourier Transform Filter, F. Da Ros, Technical University of Denmark, Department of Photonics
Engineering, Denmark, M. Nölle, Fraunhofer Institute for Telecommunications, Heinrich Hertz Institute,
Germany, C. Meuer, A. Rahim, K. Voigt, A. Abboud, I. Sackey, Technische Universität Berlin,
Fachgebiet Hochfrequenztechnik, Germany, S. Schwarz, Helmut Schmidt University, Germany, L. Molle,
Fraunhofer Institute for Telecommunications, Heinrich Hertz Institute, Germany, G. Winzer, L.
Zimmermann, IHP, Frankfurt (Oder), Germany, C. G. Schäffer, Helmut Schmidt University, Germany, J.
Bruns, K. Petermann, Technische Universität Berlin, Fachgebiet Hochfrequenztechnik, Germany and C.
Schubert, Fraunhofer Institute for Telecommunications, Heinrich Hertz Institute, Germany
We experimentally demonstrate the demultiplexing of 8×13.4 Gbaud OFDM-QPSK subcarriers using a
silicon nanophotonic-based discrete Fourier transform (DFT) filter. All eight subcarriers showed less than
1.5 dB OSNR penalty compared to the theoretical limit.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session MH2: Nanophotonic Devices I
Session Chair: Gennady Shvets, University of Texas, USA
MH2.1 10:30 AM - 11:00 AM (Invited)
Nanophotonic Design for Broadband Light Management, H. A. Atwater, MSE, USA, E. Kosten, D.
Callahan, K. W. Horowitz and R. Pala, Thomas J. Watson Laboratories of Applied Physics, USA
We describe nanophotonic design approaches for broadband light management including i) crossedtrapezoidal Si structures ii) Si photonic crystal superlattices iii) and tapered and inhomogeneous diameter
III-V/Si nanowire arrays.
MH2.2 11:00 AM - 11:15 AM
Electrically Injected nanoLED with Enhanced Spontaneous Emission From a Cavity Backed
Optical Slot Antenna, S. A. Fortuna, M. Eggleston, K. Messer, E. Yablonovitch and M. C. Wu, UC
Berkeley, USA
We propose enhancing the rate of spontaneous emission from an electrically injected nanoLED with a
cavity backed optical slot antenna. Initial experimental results show 2x higher intensity of light emission
with polarization parallel with the antenna mode indicating the presence of spontaneous emission
enhancement.
MH2.3 11:15 AM - 11:30 AM
Directional Control of Light-Emitting-Device Emission Via Sub-micron Dielectric Structures, Y.
Motoyama, Y. Hirano, K. Tanaka, N. Saito, H. Kikuchi and N. Shimidzu, NHK (Japan Broadcasting
Corporation), Japan
We fabricated optical devices containing sub-micron cylindrical structures. Most stray light is reduced by
using a shielding film. Therefore, we can obtain a principal axis with a large deflection angle and sharply
defined shape.
MH2.4 11:30 AM - 12:00 PM (Invited)
Nonreciprocal Plasmonics, H. Giessen, University of Stuttgart, Germany
12:00 PM - 1:30 PM
Lunch Break
1:30 PM - 3:30 PM
Session MA3: Nanobiophotonics and Optofluidics
Session Chair: Andreas Vasdekis, Pacific Northwest National Lab, USA
MA3.1 1:30 PM - 2:00 PM (Invited)
Ultrasensitive Digital Detection of Nanoparticles: Viral Diagnostics and Multiplexed Protein and
Nucleic Acid Assays, M.S. Ünlü, Boston University, USA
Single Particle Interferometric Reflectance Imaging Sensor (SP-IRIS) with the ability to detect single
nanoscale particles in a robust and inexpensive configuration is a promising tool for a wide range of
diagnostic applications from direct detection of viral pathogens to multiplexed protein and nucleic acid
assays.
MA3.2 2:00 PM - 2:15 PM
Spaser Powered Photothermal Cancer Therapy using Graphene and Carbon Nanotubes, C.
Rupasinghe, W. Zhu and M. Premaratne, Monash University, Australia
We propose a new cancer treatment technique in which graphene nanoflakes and carbon nanotubes
operate as a self-assembled cluster of spasers near cancer cells causing selective destruction of them by an
amplified electric field.
MA3.3 2:15 PM - 2:30 PM
Raman Characterization of DNA-CTMA Biopolymer and its Application for Ridge Waveguide
with PDMS Clad, W. Jung, Yonsei University, Korea, H. Jun, Korea Advanced Institute of Science and
Technology, Korea, B. Paulson, T. Nazari, Yonsei University, Korea, Y. Nam, Korea Advanced Institute
of Science and Technology, Korea and K. Oh, Yonsei University, Korea
We fabricated solid thin film composed of DNA complexes based on cetyltrimethylammonium. We
developed a re-crystallization process that can reduce the hydroxyl contents significantly, which were
confirmed by the Raman spectra measurements. DNA-CTMA film was deposited on a PDMS channel to
form a ridge waveguide.
MA3.4 2:30 PM - 3:00 PM (Invited)
Optofluidic Laser Based Biodetection, X. Fan, University of Michigan, USA
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session MB3: TFTs and Displays
Session Chair: Peyman Servati, University of British Columbia, Canada
MB3.1
1:30 PM - 2:00 PM (Invited)
Solution-Deposited Oxide TFTs and Backplanes, R. Street, T. Ng, R. A. Lujan, Palo Alto Research
Center, USA and T. Lee, Samsung Fine Chemicals Co., Ltd., Korea
IGZO metal oxide TFTs are fabricated from solution by sol-gel processing of In, Ga and Zn precursors.
TFT mobility of about 20 cm2/Vs was achieved in various device configurations. The performance of
solution-deposited TFT backplanes will also be described.
MB3.2
2:00 PM - 2:30 PM (Invited)
Is Quantum-Dot LCD Ready for Prime Time?, Z. Luo, CREOL, University of Central Florida, USA,
Y. Chen, Univeristy of Central Florida, USA, D. Xu and S. Wu, CREOL, University of Central Florida,
USA
Quantum dots (QDs) backlight brings several advantages to LCDs, including wider color gamut, higher
light efficiency, enhanced ambient contrast ratio, and over 100X smaller color shift. The prime time for
QD-enhanced LCDs is around the corner.
MB3.3
2:30 PM - 2:45 PM
Flexible AMOLED Display Using an Oxide-TFT Backplane and Inverted OLEDs, Y. Nakajima, T.
Takei, G. Motomura, T. Tsuzuki, H. Fukagawa, M. Nakata, H. Tsuji, T. Shimizu, Japan Broadcasting
Corporation, Sci. & Tech. Res. Labs., Setagaya-ku, Japan, K. Morii, M. Hasegawa, Nippon Shokubai
Co., Ltd., Japan, Y. Fujisaki, T. Kurita and T. Yamamoto, Japan Broadcasting Corporation, Sci. & Tech.
Res. Labs., Japan
An oxide-TFT-driven flexible AMOLED display using inverted OLEDs was fabricated. The fabricated
TFT backplane exhibited good electrical characteristics, and we confirmed the display could show color
moving images.
MB3.4
2:45 PM – 3:00 PM
Alternating Driving Scheme with Filter Circuitry for White Organic Light-Emitting Diode
Lighting, H. Yang, Y. Chen, W. Chang, Dept of Electro-Optical Eng, National Taipei University of
Technology, Taiwan, Republic of China
We found it is feasible to reduce RMS power to 55% after of applying alternating driving scheme with
filter circuitry for a 2x2 matrix white organic light-emitting diodes (WOLED) lighting unit by equivalent
circuitry simulation.
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:15 PM
Session MC3: Transceivers Integration
Session Chair: Leif Johansson, Freedom Photonics, USA
MC3.1 1:30 PM - 2:00 PM
(Invited)
Convergence of Photonics and Electronics Manufacturing, T.L. Koch, University of Arizona, USA
Silicon photonics has advanced rapidly by exploiting VLSI front-end chip manufacturing to create
sophisticated circuits with novel nanophotonic devices. This talk will explore the potential for a second
revolution that similarly leverages back-end VLSI assembly technologies.
MC3.2 2:00 PM - 2:15 PM
100 Gb/s Photonic Integrated Circuits with over 1 Billion Field Hours of Operation and Zero Field
Failures, R. Salvatore, R. Muthiah, M. Ziari, S. DeMars, P. Evans, S. Murthy, O. Khayam, J.
Pleumeekers, E. Strzelecka, M. Missey, A. Nilsson, P. Freeman, W. Sande, T. Butrie, M. Reffle and F.
Kish, Infinera Inc., USA
Reliability data are shown for InP photonic integrated circuits (PICs) comprising 10 channels at 10 Gb/s.
Over 1.3 billion hours of field operation has been reached for PIC pairs without any field failures,
corresponding to <0.8 FIT.
MC3.3 2:15 PM - 2:30 PM
Improvements in the Silicon Photonics Design Flow: Collaboration and Standardization, T.
Korthorst, PhoeniX Software, The Netherlands, J. Pond, Lumerical Solutions, Canada, C. Cone, Mentor
Graphics, USA, A. Arriordaz, Mentor Graphics, France, A. Bakker, PhoeniX Software, The Netherlands,
R. Cao, Mentor Graphics, France, J. Ferguson, Mentor Graphics, USA, J. Klein, Lumerical Solutions,
Canada and R. Stoffer, PhoeniX Software, The Netherlands
To improve the design flow for silicon and other photonics technologies, companies from the photonics
and electronics design automation domain collaborate, to improve the integration of simulations, layout,
verification and design rule checking.
MC3.4 2:30 PM - 2:45 PM (Invited)
Silicon Photonics Device Libraries for High-Speed Transceivers, L. Verslegers, A. Mekis, T. Pinguet,
Y. Chi, G. Masini, P. Sun, A. Ayazi, K. Hon, S. Sahni, S. Gloeckner, Luxtera Inc., C. Baudot, F. Boeuf,
STMicroelectronics and P. De Dobbelaere, Luxtera Inc., USA
We report on Luxtera’s technology platform, focusing on photonic device library development. As
examples, we present approaches to design low-loss polarization-splitting grating couplers, high-speed
phase modulators and photodetectors.
2:45 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session MD3: Networking
Session Chair: Lian K. Chen, Chinese University of Hong Kong, Hong Kong
MD3.1 1:30 PM - 2:00 PM (Invited)
Elastic Optical Networking and Routing and Spectrum Assignment, M. Xia, Ericsson Research, USA
We will present our work on elastic optical networking, an emerging network paradigm for demandadaptive provisioning with high customizability. To achieve high spectrum efficiency, we study the
transmission performance of various modulation formats for on-demand provisioning, and propose an
efficient routing and spectrum assignment scheme.
MD3.2 2:00 PM - 2:30 PM (Invited)
OFDM for Short-Reach Optical Networks, N. Cvijetic, NEC Laboratories America, USA
New applications are driving emergence of diverse short-reach optical networking segments with a
common emphasis on high-speed, low-cost, and flexibility. This paper examines OFDM for short-reach
networks in light of latest R&D advances and trends.
MD3.3 2:30 PM - 2:45 PM
Topology Independent Model for Estimating Total Cost of Flexible ROADMs in NGNs, M.
Nooruzzaman, University of Quebec at Montreal, Canada, Montreal, Canada and H. Elbiaze, Université
de Québec à Montréal (UQAM), Canada
ROADMs with flexible channel and structures are essential for dynamic capacity allocation. Along with a
tradeoff between flexibility and cost, we present a model for estimating ROADM cost of a network from
the node count and average nodal degree regardless of the network topology.
2:45 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session ME3: Semiconductor Lasers Tutorial
Session Chair: Dieter Bimberg, TU Berlin, Germany
ME3.1 1:30 PM - 3:00 PM (Tutorial)
TBD, V. Sorger, George Washing University, USA
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session MF3: Cavity Optomechanics and Optical Forces in Microcavities
Session Chair: A. Matsko, OEWaves, USA
MF3.1
1:30 PM - 2:00 PM (Invited)
Optomechanical Gas, T. Carmon, Technion, Israel
MF3.2
2:00 PM - 2:30 PM (Invited)
Resonant Optical Forces Associated with Whispering Gallery Modes in Microparticles, A. V.
Maslov, M. I. Bakunov, University of Nizhny Novgorod, Russia, Y. Li and V. N. Astratov, University of
North Carolina at Charlotte, USA
Resonant scattering of radiation by particles implies a significant change of the incident electromagnetic
momentum flow and, consequently, large forces on the particles. We study and compare the forces and
their relation to the momentum of the incident free-space and guided waves in various geometries.
MF3.3
2:30 PM - 2:45 PM
Nanophotonic Microfluidic Sensor and Manipulator, M. Sumetsky, Aston University, UK
Resonant structures created along a thin capillary by nanoscale deformation of its surface can perform
comprehensive sensing and manipulation of microfluids. The concept is illustrated with a model of
triangular bottle resonator and floating microparticles.
MF3.4
2:45 PM - 3:00 PM
High-Q Silica Zipper Cavity with Strong Opto-Mechanical Coupling for Optical Radiation
Pressure Driven Directional Switching, T. Tetsumoto and T. Tanabe, Keio University, Japan
We study a radiation pressure driven optical directional switch with a high-Q silica-zipper cavity
numerically. We showed the feasibility of a switch with a 17.8-dB extinction ratio.
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:15 PM
Session MG3: Fiber Nonlinearity & Modulation
Session Chair: Matt Mazurczyk, TE SubCom, USA
MG3.1 1:30 PM - 1:45 PM
The Impact of Spectral Inversion Placement for Nonlinear Phase Noise Mitigation in Non-Uniform
Transmission Links, I. Kim, O. Vassilieva, P. Palacharla and M. Sekiya, Fujitsu Laboratories of
America, Inc., USA
We show that SI provides significant Q improvement for coherent transmission even with a placement of
~15 % offset from mid-span. Multiple SIs improve nonlinear transmission performance for mixed fiber
links.
MG3.2 1:45 PM - 2:00 PM
Performance Comparison of Autonomous Software-Defined Coherent Optical Receivers, P. Isautier,
J. Pan, J. Langston, S.E. Ralph, Georgia Institute of Technology, USA
We compare the merits of two fully autonomous coherent optical receiver architectures including an
investigation of robustness to nonlinearities using experimental 31.5Gbaud-OOK/BPSK/QPSK/16-QAM
waveforms after 810km transmission. The first architecture performs modulation format recognition using
a pure higher-order-statistics method whereas the second utilizes Stokes space analysis.
MG3.3 2:00 PM - 2:15 PM
OFDM Symbol Synchronization with reduced Complexity based on Virtual Subcarriers, R.
Bouziane, University College London, UK
This paper presents a method for optical OFDM symbol synchronization using a low number of
optimally-placed virtual subcarriers. It offers significant reduction in complexity and bandwidth overhead
which makes it suitable for practical implementation.
MG3.4 2:15 PM - 2:45 PM (Invited)
Models to Predict the Nonlinear Noise Waveform and the Application in Nonlinear Compensation,
Z. Tao, Fujitsu R&D Center, China, Y. Zhao, Fujitsu R&D Center, China, Y. Fan, L. Dou, Y. Xu, Fujitsu
R&D Center, China, T. Hoshida, Fujitsu Limited, Japan and J. Rasmussen, Fujitsu Laboratories, Japan
Intra-channel nonlinear noise waveform is predicted by novel nonlinear models. The accuracy reaches
95% for various modulation formats and link configurations. Using the more accurate model, the
compensation performance is increased by 1 dB.
2:45 PM - 3:15 PM
Coffee Break
1:30 PM - 3:30 PM
Session MH3: Plasmonic Metamaterials I
Session Chair: Harald Giessen, University of Stuttgart, Germany
MH3.1 1:30 P - 2:00 PM (Invited)
Plasmonic Infrared Biosensors, G. Shvets, University of Texas at Austin, USA
MH3.2 2:00 PM - 2:30 PM (Invited)
Nonreciprocity, Nonlinearity and Parity-Time Symmetry in Optical Metasurfaces and
Metamaterials, A. Alu, The Universtiy of Texas at Austin, USA, R. Fleury and D. Sounas, The University
of Texas at Austin, USA
We discuss metasurfaces and metamaterials with exotic optical properties, which can provide giant
nonlinear, nonreciprocal or parity-time symmetric response. Our findings can largely relax the limitations
on bandwidth and losses of conventional optical metamaterials.
MH3.3 2:30 PM - 2:45 PM
A Field-Assisted Method of Producing Wide-Bandgap Transparent Conductive Electrodes and its
Application to GaN-Based Vertical-Type Light-Emitting Diodes, S. Kim, T. Lee, M. Kim, J. Kwon, J.
Park, B. Lee, D. Kang, K. Kim, School of Electrical Engineering, Korea University, Korea, E. Lee, M.
Kang, LG Advanced Research Institute, LG Electronics, Korea and T. Kim, Korea University, Korea
We fabricated GaN-based vertical-type light-emitting diodes (VLEDs) using field-assisted silicon-nitride
electrodes. They showed a reduction in forward voltages by 5% and an increase in output powers by 21%,
when compared to the reference VLEDs.
MH3.4 2:45 PM - 3:00 PM
Asymmetric Light Transmission by Using 2D PT-Symmetric Photonic Nanostructure, M. Turduev,
TOBB University of Economics and Technology, Turkey
We propose for the first time a realization of a 2D PT-symmetric photonic honeycomb structure. The
structure provides a periodic modulation of the refractive index, which combined with an anti-symmetric
gain/loss distribution on the wavelength scale and leads to non-reciprocal light coupling at resonance
frequencies.
3:00 PM - 3:30 PM
Coffee Break
Plenary & Awards Ceremony
3:30 PM - 5:00 PM
Session MI4: Plenary Session I
Room: Vicino Ballroom
Session Chair: Susumu Noda, Kyoto University, Japan
MI4.1 3:30 PM - 4:15 PM (Plenary)
Hybrid Silicon Photonic Integrated Circuits, J. Bowers, University of California – Santa Barbara, USA
MI4.2 4:15 PM – 5:00 PM (Plenary)
Single Molecule Imaging and Nanometry: Fluctuation and Function of Life, T. Yanagida, Osaka
University, Japan
5:00 PM – 6:00 PM Awards Ceremony
Welcome Reception
6:00 PM – 7:30 PM
Room: Aventine ABCG
Chair: Susumu Noda, Kyoto University, Japan
6:00 PM – 7:30 PM Welcome Reception
Tuesday, October 14, 2014
8:30 AM - 10:30 AM
Session TuA1: Advancements in Avalanche Photodiodes
Session Chair: Joe Campbell, University of Virginia, USA
TuA1.1 8:30 AM - 9:00 AM (Invited)
Photon Counting Imagers Based on High-Fill-Factor Silicon Geiger-Mode Avalanche Photodiode
Arrays, B. F. Aull, MIT, USA, D. R. Schuette, D. J. Young, D. M. Craig, B. J. Felton and K. Warner
Geiger-mode avalanche photodiodes (APDs) have been used as single-photon-sensitive optical detectors
for applications such as lidar imaging, laser spectroscopy, and optical communications. They are biased
above the avalanche breakdown voltage, where the absorption of a single photon by the diode can trigger
a self-sustaining avalanche
TuA1.2 9:00 AM - 9:15 AM
Analytical Model for Impact Ionization in 3D Multiplication Regions, G. El-Howayek, University of
New Mexico, USA, B. M. Milner, Purdue University, USA, P. Senanayake, D. L. Huffaker, University of
California at Los Angeles, USA and M. M. Hayat, University of New Mexico, USA
An analytical model for avalanche process in 3D multiplication regions is presented. Nanowires are
distinguished by this phenomenon due their flexibility in forming axial and radial junctions.
TuA1.3 9:15 AM - 9:30 AM
Low Breakdown Voltage CMOS Compatible p-n Junction Avalanche Photodiode, M. Hossain,
University of New Mexico, Albuquerque, USA
Breakdown voltage, mean gain and excess noise factor of CMOS-compatible p-n junction silicon
avalanche photodiodes are predicted using the dead space multiplication theory. Measured dark current
and breakdown voltages are also reported supporting low-voltage operation.
TuA1.4 9:30 AM - 10:00 AM (Invited)
High-Speed High-Power-Tolerant Avalanche Photodiode for 100-Gb/s Applications, M. Nada, Y.
Muramoto, H. Yokoyama and H. Matsuzaki, NTT Photonics Laboratories, NTT Corporation, Japan
This paper reviews our work on a high-speed and high-power-tolerant avalanche photodiode (APD). The
APD exhibits large 3-dB bandwidth for a wide input power range. Receiver characteristics using the APD
for 100-Gb/s applications are also introduced.
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session TuB1: Systems and Architectures for Optical Interconnects
Session Chair: Mike Haney, University of Delaware, USA
TuB1.1 8:30 AM - 8:45 AM
Scalable and High Performance HPC Architecture with Optical Interconnects, Z. Cao, R. Proietti
and S. Yoo, University of California, Davis, USA
We propose a HPC architecture that overcomes I/O limitations by exploiting silicon photonics and optical
backplanes with WDM wavelength routing. Compared with fat-tree, 2.5 times throughput with 20% less
global switches and cables is achieved.
TuB1.2 8:45 AM - 9:15 AM (Invited)
Integration Technologies and Packaging for Efficient Si Photonics Links, J. Cunningham, Oracle,
USA
TuB1.3 9:15 AM - 9:45 AM (Invited)
MMF Transmission at 1310nm Using Integrated Silicon Photonics Transceiver, X. Chen, B. R.
Scott, Corning Incorporated, USA, H. Liu, O. I. Dosunmu, Intel Corporation, USA, J. Hurley and M. Li,
Corning Incorporated, USA
We present the benefit of MMF operated at long wavelength and demonstrate 25Gb/s transmission over a
record 820m reach using multimode launch from integrated SiPh transceiver through MMF optimized for
high bandwidth at 1310nm.
TuB1.4 9:45 AM - 10:15 AM (Invited)
Lighting as an Opportunistic Platform for Converged Heterogeneous Networks, T. Little, Boston
University, USA
10:15 AM - 10:30 AM Coffee Break
8:30 AM - 11:00 AM
Session TuC1: Advanced Microwave Photonics Components
Session Chair: Bill Jacobs, SPAWAR Systems Center Pacific, USA
TuC1.1 8:30 AM - 8:45 AM
Ultra Wide Bandwidth Electro-optic Intensity Modulators with 0.46 V-cm Modulation Efficiency at
1550 nm, S. Dogru and N. Dagli, UCSB, USA
Intensity modulators using substrate-removed waveguides and loaded line traveling wave electrodes are
presented. 10 mm and 5 mm long electrode devices have 0.77 V and 1.54 V and bandwidth exceeding 67
GHz at 1550 nm.
TuC1.2 8:45 AM - 9:00 AM
A True Linear Intensity Modulator for Pulsed Light, E. Sarailou, A. Ardey and P. Delfyett, CREOL,
University of Central Florida, USA
A linear interferometric intensity modulator for pulsed light is demonstrated using an injection-locked
mode-locked laser (MLL). A spur free dynamic range (SFDR) of 105 dB.Hz2/3 is obtained by
modulating the voltage of the saturable absorber.
TuC1.3 9:00 AM - 9:30 AM (Invited)
Array-Antenna-Electrode Electro-Optic Modulator for Millimeter-Wave Wireless Signal
Discrimination, H. Murata, N. Kohmu, T. Ikeda and Y. Okamura, Graduate School of Engineering
Science, Osaka University, Japan
60 GHz-band wireless 4-channel SDM signals were discriminated using an array-antenna-electrode
electro-optic modulator with multiple channel waveguides and polarization reversal structures.
Conversion to an IF-band signal using photonic technology is also discussed with preliminary
experiments.
TuC1.4 9:30 AM - 9:45 AM
Modeling Nonlinearity in a Partially Depleted Absorber Photodetector and a Modified UniTraveling Carrier Photodetector, Y. Hu, C. R. Menyuk, UMBC, USA, M. Hutchinson, V. J. Urick and
K. J. Williams, Naval Research Laboratory, USA
We investigate the sources of nonlinearity in a partially depleted absorber (PDA)photodetector and a
modified uni-traveling-carrier (MUTC) photodetector. The Franz-Keldysh effect and impact ionization
are the two most important sources of nonlinearity.
TuC1.5 9:45 AM - 10:00 AM
Widely Tunable Microwave Photonics Notch Filter Based on a Waveguide Bragg Grating on
Silicon, M. Burla, Institut National de la Recherche Scientifique, Canada, H. Pishvai Bazargani, INRSEMT, Canada, J. St-Yves, W. Shi, Center for Optics, Photonics, and Lasers (COPL), Canada, L.
Chrostowski, University of British Columbia, Canada and J. Azana, INRS-EMT, Canada
We experimentally demonstrate a broadband, frequency agile RF-photonic notch filter based on a
waveguide Bragg grating on silicon. The device shows a seamless notch RF frequency tuning over 20
GHz without changes in the shape of the filter response.
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session TuD1: Special Symposium on High Power Diode Lasers and Systems I
Session Chair: Berthold Schmidt, TRUMPF Laser Marking Systems AG, Switzerland
TuD1.1 8:30 AM - 9:00 AM (Invited)
High-Power Diode Lasers – a Look Towards the Future, E. Zucker, JDSU, USA
In 2014, the overall laser market is forecasted to exceed $9 billion dollars. We estimate that at least $1
billion can be attributed to high power laser diodes, either directly in sales, or as the value of pumps
within other lasers.
TuD1.2 9:00 AM - 9:30 AM (Invited)
Thin Film Filter Wavelength-Locked Laser Cavity for Spectral Beam Combining of Diode Laser
Arrays, H. Zimer, M. Haas, S. Ried, C. Tillkorn, A. Killi, TRUMPF Laser GmbH, Germany, S.
Heinemann, V. Negoita, H. An, TRUMPF Photonics, Inc., USA and B. Schmidt, TRUMPF Lasermarking
Systems AG, Switzerland
We describe a novel wavelength-stabilized multi-laser cavity, suited for kW-class dense spectral beam
combining of broad-area diode laser emitters. The approach has been used to demonstrate spectral beam
combining of multiple low fill-factor bars into a 100 µm fiber.
TuD1.3 9:30 AM - 10:00 AM (Invited)
Commercial High Efficiency Broad Area Diode Lasers for Industry, R. Martinsen, nLight Inc., USA
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session TuE1: DFB, DBR and Short Pulses
Session Chair: Gadi Eisenstein, Technion Haifa/TU Berlin, Germany
TuE1.1 8:30 AM - 9:00 AM (Invited)
Index-Coupled Quantum-Dot DFB Lasers, M. Stubenrauch, G. Stracke, D. Arsenijevic, A. Strittmatter
and D. Bimberg, Technical University Berlin, Germany
The static and dynamic properties of p-doped quantum-dot distributed-feedback lasers based on pure
index-gratings are presented. Optical output power up to 34 mW, 58 dB SMSR, and 15 Gb/s error-free
data rate are shown.
TuE1.2 9:00 AM - 9:15 AM
Low Distortion 1550 nm GaInAsP DFB Lasers for DigitalQAM and Analog Forward Path
Applications, H. Lin, Applied Optoelectronics, Inc., USA
Highly linear and price competitive 1550nm GaInAsP DFB RWG lasers with low distortions and
low chirps for QAM applications was developed. Their frequency dependent CTB was studied
through band gap engineering in the active region.
TuE1.3 9:15 AM - 9:30 AM
Mode-Locking and Frequency Mixing at THz Repetition Rates in a Sampled-Grating DBR ModeLocked Laser , L. Hou, J. H. Marsh and M. Haji, University of Glasgow, UK
We report a laser with two different SGDBRs that mode-lock at 640 and 700 GHz repetition rates,
respectively. Stable pulse trains at 640 GHz, 666 GHz, and 1.34 THz are observed under particular
driving conditions
TuE1.4 9:30 AM - 9:45 AM
Extending the Repetition Rate of Passively Mode-Locked Quantum Dot Lasers, D. Murrell,
University of New Mexico, USA, R. Raghunathan and L. Lester, Virginia Tech, USA
A model for passive mode-locking is presented that enables analysis of the output repetition rate stability
as a function of device properties and clarifies the importance of the differential absorption, unsaturated
absorption and internal loss.
TuE1.5 9:45 AM - 10:00 AM
Dispersion Optimization in a Semiconductor Optical Frequency Comb, A. Klee, K. Bagnell and P.
Delfyett, CREOL, College of Optics and Photonics at Univerisity Central Florida, USA
We investigate the optimal amount of dispersion compensation for maximum spectral bandwidth of an
optical frequency comb from an external fiber cavity semiconductor laser with intracavity etalon.
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session TuF1: Transmission and Related Effects
Session Chair: Odile Liboiron-Ladouceur, McGill University, Canada
TuF1.1 8:30 AM - 8:45 AM
DP-CS-DQPSK 32x112 Gbit/s Signal Transmission in a Transparent Core Optical Network , S.
Fazel, M. Lourdiane and C. Lepers, Institut Mines-Telecom/Telecom SudParis, Evry Cedex, France
DP-CS-DQPSK transmitter and receiver with dual RF carriers are deployed for a non-coherent signal
transmission in a medium/long reach transparent core network. BER performance evaluation leads to a
3000km maximum optical reach at OSNR=20dB.
TuF1.2 8:45 AM - 9:00 AM
Cascaded ROADM Tolerance of mQAM Optical Signals Employing Nyquist Shaping, M. Filer and
S. Tibuleac, ADVA Optical Networking, Norcross, USA
Tolerance to cascaded WSS filtering is studied for QPSK, 8QAM, and 16QAM formats operating at 32
GBaud. Channel spacing, WSS filter shape, and DSP parameters are considered, and recommendations
are made for performance optimization using methods which are practically implementable in modern
hardware.
TuF1.3 9:00 AM - 9:30 AM (Invited)
Digital and Analog Signal Transmission Technologies Based on Multi-Level Modulation and
Precise Lightwave Control, T. Kawanishi and A. Kanno, National Institute of Information and
Communications Technology, Japan
This presentation shows precise lightwave control and multi-level modulation techniques for analog and
digital signal transmission. Digital signal processing can mitigate signal degradation in seamless access
communication systems of wired and wireless links.
TuF1.4 9:30 AM - 9:45 AM
Nonlinear Impact of Diverse Optical Routing in Uncompensated 120 Gb/s PM-QPSK Links, S.
Searcy and S. Tibuleac, ADVA Optical Networking, USA
We experimentally examine nonlinear penalties for 120 Gb/s PM-QPSK signals in uncompensated links
with co-propagating channels added and dropped along the link. Dependencies on add/drop frequency and
pre-dispersion on the add channels are also investigated.
9:45 AM - 10:30 AM Coffee Break
8:30 AM - 10:15 AM
Session TuG1: 100G and Emerging Transmission Technologies
Session Chair: Leif Oxenlowe, Fotonik
TuG1.1 8:30 AM - 8:45 AM
Impact of Clock-Phase Misalignment on optical Multiplexing for Time-Interleaved CarrierSuppressed Return-to-Zero Signaling, T. Sakamoto, National Institute of Information and
Communications Technology (NICT), Japan
We investigate clock phase dependence of optical multiplexing for time-interleaved carrier-suppressed
return-to-zero (TI-CSRZ) format. Nyquist shaping on electrical tributary signals and/or multi-input-multioutput equalization with two-tone detection in a receiver side absorbs the clock-phase misalignment.
TuG1.2 8:45 AM - 9:00 AM
Uncooled MIMO DWDM Using Pulse-Amplitude Modulation and Adaptive Crosstalk
Cancellation, J. B. von Lindeiner, R. V. Penty and I. H. White, University of Cambridge, UK
We present a proof-of-principle low-cost, uncooled, multiple-input-multiple-output (MIMO) dense
wavelength division multiplexed (DWDM) system using advanced coding to allow for a greater stable
operating region to be realized in terms of minimum channel spacing. For 400 GbE, a power consumption
saving of 39% is estimated.
TuG1.3 9:00 AM - 9:30 AM (Invited)
Recent Progress in 100G Unrepeatered Transmission, D. Chang, W. Pelouch, S. Burtsev, P. Perrier
and H. Fevrier, Xtera Communications, Inc., USA
This paper reviews the main technologies in 100G unrepeatered transmission systems and describes
experimental demonstrations of long reach and high capacity based on PM-QPSK modulation with a
coherent receiver.
TuG1.4 9:30 AM - 9:45 AM
Phase-Conjugated Twin Signals Generation with Oppositely-Biased Paired IQ Modulators, T.
Sakamoto, National Institute of Information and Communications Technology (NICT), Japan, G. Lu and
T. Kawanishi, NICT, Japan
We propose and demonstrate phase-conjugated twin signals generation using oppositely-biased paired IQ
modulators. Phase conjugation is electro-optically realized without relying on electrical-domain
processing. Nonlinear phase shift of 20-Gb/s QPSK is experimentally compensated for.
9:45 AM - 10:15 AM Coffee Break
8:30 AM - 10:30 AM
Session TuH1: Nanophotonic Devices II
Session Chair: Ahmet Ali Yanik, University of California, Santa Cruz, USA
TuH1.1 8:30 AM - 8:45 AM
Novel Optical Antenna Designs of Comb Shaped Split Ring Architecture for NIR and MIR
Enhanced Field Localization, V. T. Kilic, Bilkent University, Turkey, V. Erturk and H. V. Demir,
Bilkent University, Electrical and Electronics Engineering Department, Turkey
We demonstrated NIR/MIR resonance behavior in optical antennas of comb-shaped split-ring resonators
enabling substantially larger field enhancements than single/array of dipoles with the same side length,
despite their simple architecture.
TuH1.2 8:45 AM - 9:00 AM
Metamaterials Strongly Coupled to Intersubband Transitions: Circuit Model and Second Order
Nonlinear Processes, S. Campione, Sandia National Laboratories, USA, A. Benz, O. Wolf, J. F. Klem,
Sandia National Laboratories, USA, F. Capolino, University of California Irvine, USA, M. B. Sinclair and
I. Brener, Sandia National Laboratories, USA
We present an electrodynamic model of strongly coupled metamaterial/intersubbandtransition systems
that can be used to predict and maximize Rabi splittings. This model can also be used to optimize
metamaterial structures that enhance second-order nonlinear processes.
TuH1.3 9:00 AM - 9:15 AM
Great Light Absorption Enhancement in a Graphene Metamaterial Photodetector, Q. Chen, S.
Song, L. Wen, L. Jin, Y. Yu and F. Sun, Suzhou Institute of Nano-Tech and Nano-Bionics, Chinese
Academy of Science, China
A photodetector with graphene embedded in a metamaterial perfect absorber (MPA) is proposed. 17 times
light absorption enhancement is obtained compared to a graphene monolayer. Cascaded MPAs integrated
with graphene are investigated as multiband photodetectors.
TuH1.4 9:15 AM - 9:30 AM
Employing Metamaterial for Enhanced THz Generation in Photomixers, D. J. Ironside, University of
Texas at Austin, USA
Utilizing high thermally-conductive copper substrates and E-patch antennas, we propose a new THz
photomixer design. Our analysis indicates that such a THz photomixer design may generate continuous
wave powers in the milliwatt range and, through photoconductive gain, exceed the Manley-Rowe limit up
to 2 THz.
TuH1.5 9:30 AM - 10:00 AM (Invited)
Plasmonics Enhanced Terahertz Radiation from Large Area Photoconductive Emitters, N. T.
Yardimci, S. Yang, UCLA Electrical Engineering Department, USA, C. W. Berry, University of
Michigan, Ann Arbor, USA and M. Jarrahi, UCLA Electrical Engineering Department, USA
We present a novel large area plasmonic photoconductive emitter and demonstrate pulsed terahertz
generation with radiation powers as high as 3.6 mW at an optical pump power of 150 mW over 0.1-3 THz
frequency range.
10:00 AM - 10:30 AM Coffee Break
10:30 AM - 1:30 PM
Session TuA2: 3D Imaging Techniques
Session Chair: John David, University of Sheffield, UK
TuA2.1 10:30 AM - 11:00 AM (Invited)
3D Computational Ghost Imaging, B. Sun, M. Edgar, R. Bowman, SUPA, School of Physics and
Astronomy, University of Glasgow, UK, L. Vittert, School of Mathematics and Statistics, University of
Glasgow, UK and M. Padgett, SUPA, School of Physics and Astronomy, University of Glasgow, UK
Ghost Imaging uses a series of projected illumination patterns and a measurement of the total
backscattered light to deduce the image of an object under illumination. The shadows in such images
depend upon the relative position of the pattern projector and the detector. Using multiple
TuA2.2 11:00 AM - 11:30 AM (Invited)
New Technologies and Perspective for 3D-Imaging, B. Lee, S. Park, N. Chen, J. Yeom, K. Hong and J.
Kim, Seoul National University, Korea
Acquisition and visualization of three-dimensional information based on light field imaging technique is
attractive due to its high compatibility. We introduce imaging techniques including real-time pickupdisplay systems and light field hologram generation.
TuA2.3 11:30 AM - 11:45 AM
Characterizing Microdroplet Evaporation Using Diffraction Phase Microscopy, C. Edwards,
University of Illinois at Urbana-Champaign, USA, A. Arbabi, B. Bhaduri, University of Illinois at
Urbana-Champaign, USA, R. Ganti, University of Pennsylvania, USA, P. J. Yunker, Harvard University,
USA, A. G. Yodh, University of Pennsylvania, USA, G. Popsecu, University of Illinois, USA and L. L.
Goddard, University of Illinois at Urbana-Champaign, USA
Diffraction phase microscopy is a non-destructive in-situ characterization tool with nanometer height
resolution that can measure 3-dimensional topography. We apply it to characterize microdroplets during
evaporation without any a priori assumptions about the droplet geometry.
11:45 AM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session TuB2: Integration of Sources for Optical Interconnects
Session Chair: Eric Johnson, Clemson University, USA
TuB2.1 10:30 AM - 10:45 AM
Enhanced Photoluminescence From Ge/SiGe Quantum Wells byEpitaxial Growth Induced Strain,
X. Chen, Y. Huo, E. Fei, C. Lu, K. Zang, M. Xue, T. Kamins and J. Harris, Stanford University, USA
We demonstrate enhanced photoluminescence from Ge/SiGe quantum wells with strain from -0.28%
(compressive) to 0.25% (tensile) achieved by epitaxial growth techniques. The intensity enhancement and
peak shift from photoluminescence measurements are in agreement with theoretical calculations.
TuB2.2 10:45 AM - 11:15 AM (Invited)
Optical Antenna-Coupled Nano-LED for Energy-Efficient On-Chip Interconnect, M. Wu,
University of California Berkeley, USA
TuB2.3 11:15 AM - 11:45 AM (Invited)
III-V On-Silicon Sources for Optical Interconnect Applications, D. Van Thourhout, Ghent University
/ IMEC, Belgium, S. Keyvaninia, M. Tassaert, T. Speusens, G. Roelkens, B. Tian, Z. Wang, Ghent
University / IMEC, Belgium, M. Pantouvaki and C. Merckling, IMEC, Belgium
Optical interconnects require efficient and flexible optical sources. This paper presents results on two
technology platforms being developed for realizing these. Integration using wafer bonding technologies is
well established now and the focus is on new device types including tunable lasers, multi-wavelength
lasers and switching.
TuB2.4 11:45 AM - 12:00 PM
Heterogeneously Integrated Long Wavelength VCSEL Based Transceivers for Data Center
Networks, R. Rivers, K. Kormirisetty and D. Geddis, Norfolk State University, USA
As data centers continue to consolidate, the demand for cost effective optical links will increase. The
research presented herein includes the design and fabrication of a long wavelength VCSEL-based optical
transceiver for such for links.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session TuC2: Photonic Microwave Signal Processing
Session Chair: Vincent Urick, Naval Research Lab, USA
TuC2.1 10:30 AM - 11:00 AM (Invited)
Microwave Photonic Signal Processing Based on Polarization Modulation, S. Pan and Y. Zhang,
Nanjing University of Aeronautics and Astronautics, China
Polarization modulation can provide the microwave photonic signal processing systems unprecedented
flexibilities. A variety of polarization-modulation-based microwave photonic signal processing functions
have been realized with high performance, simple configuration and flexible operation.
TuC2.2 11:00 AM - 11:15 AM
Coherent Optical Pulse Shaping From Incoherent Light Sources, R. Ashrafi, McGill University,
Department of Electrical and Computer Engineering, Canada, M. Li, Institute of Semiconductors,
Chinese Academy of Sciences, China, J. Azaña, INRS (Institut national de la recherche scientifique),
Canada and L. Chen, McGill University, Department of Electrical and Computer Engineering, Canada
Using the spectral coherence properties of temporally modulated incoherent fields, a novel optical pulse
shaping approach for obtaining a fully coherent optical waveform with a customized temporal shape from
a time-gated incoherent light source is introduced and numerically demonstrated.
TuC2.3 11:15 AM - 11:30 AM
Microwave Photonic Self-Interference Cancellation System Using a Slow and Fast Light Delay
Line, M. P. Chang, J. Wang, M. Lu, Princeton University, USA, D. Fisher, The College of New Jersey,
USA, B. Chen and P. R. Prucnal, Princeton University, USA
We demonstrate a microwave photonic system to perform wideband, radio frequency self-interference
cancellation. The tunable optical time delay is implemented using a novel semiconductor slow and fast
light delay line that enables fast electrical control.
TuC2.4 11:30 AM - 11:45 AM
Photonic-Assisted Endoscopic Analysis of W-Band Waveguide, D. Lee, KRISS, Korea, J. Kwon, Y.
Hong, Korea Research Institute of Standards and Science, Korea and J. Jargon, National Institute of
Standards and Technology, USA
We demonstrate an endoscopic probing system to measure field distribution through a W-band
waveguide. The electric fields propagating inside a WR-10 waveguide are measured utilizing W-band
harmonics of a femtosecond laser with a minute photonic probe.
TuC2.5 11:45 AM – 12:00 PM
Photonic Time-Stretched Analog-to-Digital Converter with Suppression of Dispersion-Induced
Power Fading Based on Polarization Modulation, X. Ye, F. Zhang and S. Pan, Nanjing University of
Aeronautics and Astronautics, China
A photonic time-stretched analog-to-digital converter with suppression of dispersion-induced power
fading is proposed using polarization modulation. A 32-GHz single-tone input, which should undergo the
largest dispersion impairment, is experimentally stretched by a factor of ~9.5.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session TuD2: Special Symposium on High Power Diode Lasers and Systems II
Session Chair: John Marsh, University of Glasgow, Scotland
TuD2.1 10:30 AM - 11:00 AM (Invited)
Direct Diode Lasers for Industrial Sheet Metal Cutting and Welding, R. K. Huang, B. Chann and P.
Tayebati, TeraDiode, Inc., USA
TeraDiode is manufacturing the first high brightness direct diode laser for industrial laser sheet metal
cutting and welding. TeraDiode’s core technology is based on Wavelength Beam Combination (WBC)
which was developed at MIT Lincoln Laboratory. Using WBC technology, TeraDiode has demonstrated a
100x brightness enhancement
TuD2.2 11:00 AM - 11:30 AM (Invited)
Near-Infrared Digital Heating Solutions with Power VCSEL Arrays, A. Pruijmboom, R. Conrads, C.
Deppe, G. Derra, S. Gronenborn, X. Gu, G. Heusler, J. S. Kolb, Philips GmbH Photonics Aachen, M.
Miller, Philips GmbH Photonics Ulm, H. Moench, F. Ogiewa, P. Pekarski, J. Pollmann-Retsch and U.
Weichmann, Philips GmbH Photonics Aachen, Germany
Thermal processes play an essential role in the production and processing of countless industrial and
consumer products. Narrow bandwidth near infrared (NIR) light allows contactless transfer of energy
with a high power per area that can be tailored to the needs of the application.
TuD2.3 11:30 AM - 12:00 PM (Invited)
High-Power Diode Laser Arrays for Large Scientific Lasers and Inertial Fusion, R. Deri, A. J.
Bayramian, A. C. Erlandson, S. Patra, A. M. Dunne, D. Flowers, S. Telford, S. Fulkerson and K.
Schaffers, Lawrence Livermore National Laboratory, USA
Several large scale laser applications require diode pumps for high efficiency and average power, but are
sensitive to diode performance-cost tradeoffs. This paper describes approaches for addressing these issues
in pulsed laser systems, using an example of inertial fusion energy drivers.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session TuE2: Short Pulses and Amplification
Session Chair: Pallab Bhattacharya, University of Michigan, USA
TuE2.1 10:30 AM - 11:00 AM (Invited)
Nonlinear Optical Response of Quantum Dot Lasers, G. Eisenstein, Technion Haifa/TU Berlin,
Germany
TuE2.2 11:00 AM - 11:15 AM
Analytical Theory for a Quantum Dot Gain Levered Mode Locked Laser, D. A. Murrell, University
of New Mexico, USA, R. Raghunathan and L. Lester, Virginia Tech, USA
A new method of achieving mode locking using a gain lever Quantum Dot Mode Locked Laser is
proposed as an augment to traditional techniques when striving for higher repetition rates.
TuE2.3 11:15 AM - 11:30 AM
Phase-Amplitude Coupling of Optically-Injected Nanostructured Semiconductor Lasers, C. Wang,
INSA de Rennes, France, M. Chaibi, Telecom Paristech, France, B. Lingnau, Technische Universität
Berlin, Germany, D. Erasme, Telecom Paristech, France, K. Ludge, Technische Universität Berlin,
Germany, P. Poole, National Research Council Canada, Canada, j. Provost, -V Lab, a joint lab of
Alcatel-Lucent Bell Labs France, France, J. Even, Université Européenne de Bretagne, INSA, France and
F. Grillot, Telecom Paristech, France
In injection-locked lasers, the phase-amplitude coupling cannot be characterized by the FM-to-AM ratio.
The former exhibits a resonance due to the injected field and the equivalent a-factor can be larger than
that of solitary laser.
TuE2.4 11:30 AM - 12:00 PM
Finding Threshold in a Thresholdless Laser, W. Chow, Sandia National Labs, USA, F. Jahnke and C.
Gies, Bremen University, Germany
Cavity-quantum-electrodynamics is applied to address the questions of criteria and nature of lasing in
devices where the intensity jump customarily used to indicate lasing threshold is missing.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session TuF2: III-V Integration
Session Chair: Lieven Verslegers, Luxtera, USA
TuF2.1 10:30 AM - 11:00 AM (Invited)
InP Photonic Integrated Circuits for High Efficiency Optical Transceivers, Y. Akulova, JDSU,
Milpitas, CA, USA
InP PIC integration platforms enable high efficiency pluggable transceivers. Design and performance of
widely tunable and fixed wavelength PICs with electro-absorption and Mach-Zehnder modulators for 10
and 100 Gb/s datacom and telecom applications will be reviewed.
TuF2.2 11:00 AM - 11:15 AM
Monolithically Integrated InP-Based 2.25 Tb/s Coherent Photonic Integrated Circuit Transmitter,
T. Vallaitis, J. Summers, P. Evans, M. Ziari, P. Studenkov, M. Fisher, J. Sena, A. James, S. Corzine,
Infinera, USA, D. Pavinski, Infinera, USA, J. Ou Yang, M. Missey, D. Gold, D. Lambert, W. Williams,
M. Lai, F. A. Kish and D. F. Welch, Infinera, USA
We demonstrate a single-chip, monolithically integrated, dual-polarization QPSK transmitter which
combines over 1700 functions and is capable of delivering 2.25 Tb/s of bandwidth.
TuF2.3 11:15 AM - 11:30 AM
Power-Enhancement Broadband Cascaded Integration of Electroabsorption Modulator and
Semiconductor Optical Amplifier by Local Quantum Well Intermixing, Y. Chiu, NSYSU, Taiwan,
Republic of China
Using local quantum-well-intermixing and cascaded-integration technique, a high-transmission
broadband EAM-integrated SOA is demonstrated. Above 20dB-enhancement optical transmission, 57nm
wavelength shift in electro-luminance, and 40Gb/s performance are observed, enabling regrowth-free
local bandgap engineering in integration template.
TuF2.4 11:30 AM - 11:45 AM
Dual-Core Spot-Size Converter with Tapered Cladding Layer Designed for High-Efficiency Mode
Coupling to InP-Based Deep-Ridge Waveguide, T. Kitamura, N. Kono, H. Yagi, T. Ishikawa, K.
Horino, D. Kimura, M. Seki and Y. Yoneda, Sumitomo Electric Industries, Ltd., Japan
We demonstrated an InP-based dual-core spot-size converter with the tapered cladding layer designed for
high-efficiency mode coupling between two cores. It gives the wider dry-etching process tolerances,
which provides uniform and low loss coupling properties.
TuF2.5 11:45 AM - 12:15 PM (Invited)
High Performance InP Photonic Integrated Circuits, L. Johansson, M. Mašanovic, Freedom
Photonics, USA, M. Lu, H. Park, M. Rodwell, Lkuo . Coldren, University of California – Santa Barbara,
USA
We are reviewing recent results in the development of high performance Indium Phosphide photonic
integrated circuits for coherent communications applications. Integrated transmitters and receivers for fast
wavelength switched applications are presented.
12:15 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session TuG2: High Capacity Transmission Technology
Session Chair: Nikola Alic, University of California San Diego, USA
TuG2.1 10:30 AM - 11:00 AM (Invited)
Optical Frequency Combs for High-speed Transmission, B. Kuo, University of California San Diego,
USA
TuG2.2 11:00 AM - 11:15 AM
Electo-Optic Dual-Channel Coherent Signal Emulator, T. Sakamoto, National Institute of Information
and Communications Technology (NICT), Japan, G. Lu and T. Kawanishi, NICT, Japan
We demonstrate electro-optic dual-channel coherent signal emulator, where multiplexed signal is
artificially generated by using an optical IQ modulator driven with an arbitrary-waveform generator.
2x20-Gb/s dual-carrier QPSK signal generation is emulated.
TuG2.3 11:15 AM - 11:30 AM
Investigation of Interferometric In-Band OSNR Monitor for Monitoring Nyquist-Shaped 400G DPQPSK Superchannels , J. Yang, Y. Akasaka and M. Sekiya, Fujitsu Laboratories of America, USA
New operation of interferometric OSNR monitor is investigated to support Nyquist superchannels. Power
ratio in 10-30dB OSNR of 32Gbaud 4-subcarrier Nyquist DP-QPSK superchannel is increased to ~3dB
and monitored OSNR error less than +/-1dB is achieved.
TuG2.4 11:30 AM - 12:00 PM (Invited)
Capacity and Shaping in Coherent Fiber-Optic Links, J. M. Estaran, Department of Photonics
Engineering, Technical University of Denmark, Denmark, D. Zibar and I. Tafur Monroy, Department of
Photonics Engineering, Technical University of Denmark., Denmark
Overview of the concepts and latest progress of capacity and constellation shaping in coherent optical
links.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session TuH2: Plasmonic Metamaterials II
Session Chair: Ahmet Ali Yanik, University of California, Santa Cruz, USA
TuH2.1 10:30 AM - 11:00 AM (Invited)
Functional Metasurfaces, M. Brongersma, Stanford University, USA
TuH2.2 11:00 AM - 11:30 AM (Invited)
Metamaterials, Toroids and Flying Donuts, N. Zheludev, University of Southampton and NTU
Singapore, V. A. Fedotov, T. Raybould, N. Papasimakis, V. Savinov, University of Southampton, UK, I.
Youngs, DSTL, UK
We will present an overview of our current metamaterial-enabled study on the properties of peculiar
localized electromagnetic excitations topologically resembling a torous, which are allowed by Maxwell’s
electrodynamics in both matter and free space.
TuH2.3 11:30 AM - 11:45 AM
A New Robust Perfect Lens, G. Rosenblatt, G. Bartal and M. Orenstein, Department of Electrical
Engineering, Technion, Israel
A single-interface between double-negative and double-positive media acts as a robust perfect-lens whose
unbounded resolution endures loss and frequency offsets – unlike existing designs. Its mechanism and
performance are reported and compared to the slab lens.
TuH2.4 11:45 AM - 12:00 PM
Electrically Tunable Directional SPP Propagationin Gold-Nanoparticle-Assisted Graphene
Nanoribbons, D. Sikdar and M. Premaratne, Monash University, Australia
We demonstrate electrically tunable inhomogeneous surface-plasmon-propagation (SPP) over the length
of a graphene nanoribbon and a scheme to alter SPP direction by selectively boosting up graphene-SPP
strength via coupling with plasmonic nanoparticles.
12:00 PM - 1:30 PM
Lunch Break
1:30 PM - 3:30 PM
Session TuA3: Photodetectors, Sensors, Systems and Imaging Tutorial
Session Chair: Erik Duerr, Massachusetts Institute of Technology, USA
TuA3.1 1:30 PM – 3:00 PM (Tutorial)
Quantum Dot and Quantum Well Photonics, E. Towe, Carnegie Mellon, USA
This tutorial will outline current research in basic optical and quantum phenomena in materials for
applications in novel photonic devices that enable a new generation of information processing systems for
communication, computation, and sensing.
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session TuB3: Modulators and Detectors for Optical Interconnects
Session Chair: Jesse Rosenberg
TuB3.1 1:30 PM - 1:45 PM
Silicon Photonic Bragg Grating Modulators, X. Wang, M. Caverley, J. Flueckiger, Y. Wang, N. A.
Jaeger and L. Chrostowski, University of British Columbia, Canada
We report silicon photonic modulators based on Bragg grating cavities with a reverse-biased p-n junction
embedded in the grating waveguide. Modulation bandwidths exceeding 10 GHz have been obtained.
TuB3.2 1:45 PM - 2:15 PM (Invited)
Linear Modulators in Photonic BiCMOS Technology, D. Petousi, IHP-Microelectronics, Frankfurt
Oder, Germany
We review our recent work showing that Si and InP Mach-Zehnder modulators can have similar
performance, while the first offer the advantage of monolithic integration with electronics. Development
status of modulators in photonic BiCMOS is presented.
TuB3.3 2:15 PM - 2:30 PM
A Low-Voltage PAM-4 SOI Ring-Based Modulator, M. Hai, M. M. Fard and O. Liboiron-Ladouceur,
McGill University, Canada
A novel modulator for PAM-4 designed on a silicon on insulator (SOI) platform generates a clear four
level eye diagram. The forward biased modulator is driven with a 120 mVpp electrical signal without preemphasis at 120 Mb/s.
TuB3.4 2:30 PM - 2:45 PM
A Self-Equalizing Photo-Detector, B. Abiri, California Institute of Technology, USA, F. Aflatouni,
University of Pennsylvania, USA and A. Hajimiri, California Institute of Technology, USA
A self-equalizing photo-detector (SEPD) that mitigates the bandwidth limitations of electro-optical
components of optical communication systems is demonstrated, enabling higher rate of data transmission,
using slower components. Unlike other all-optical equalization schemes, SEPD is optically wide band,
thus does not require wavelength tuning.
TuB3.5 2:45 PM - 3:00 PM
Large-Area InP Based Photodiode Operated at 850 nm Wavelengths with High Efficiency and High
Speed for 40 Gbit/sec Transmission, J. Shi, C. Li, K. Chi, J. Wun, Department of Electrical
Engineering, National Central University, Taiwan, Republic of China, S. D. Benjamin, Applied Research
and Development, Corning Incorporated, USA
We demonstrate InP photodiodes with large diameter of optical window (40 um). They achieve highspeed (25 GHz) and high-responsivity (0.52 A/W) at 0.85 um wavelength. Error-free 40 Gbit/sec
transmissions over 100 meter OM4 fiber have been achieved
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session Tuc3: Integrated Microwave Photonics
Session Chair: Christina Lim, University of Melbourne, Australia
TuC3.1 1:30 PM - 2:00 PM (Invited)
Lithium Niobate Photonics on Silicon Substrates, P. Rabiei, Partow Technologies LLC, USA, J. Ma, J.
Chiles, S. Khan and S. Fathpour, The College of Optics and Photonics, University of Central Florida,
USA
A novel platform for lithium-niobate-on-silicon photonics is developed. High-index-contrast submicron
waveguides, microring resonators and optical modulators are demonstrated on the platform. The Y-cut
lithium niobate Mach-Zehnder modulators have a record-low half-voltage length-product of 4 V-cm.
TuC3.2 2:00 PM - 2:15 PM
Photonic-Assisted Microwave Frequency Doubling based on Silicon Ring Modulator, H. Shao,
Zhejiang University, China & Gent University, Belgium, X. Jiang, J. Yang, Zhejiang University, China,
Y. Hu, G. Roelkens, Gent University, Intec, Photonics Research Group, Belgium and H. Yu, Zhejiang
University, China
We experimentally demonstrate an integrated optical millimeter-wave signal generator based on a silicon
ring modulator. A 20 GHz microwave signal with 17 dB suppression ratio is obtained with a 10 GHz
input signal.
TuC3.3 2:15 PM - 2:45 PM (Invited)
TriPleX™: The Low Loss Passive Photonics Platform, R. Heideman, A. Leinse, M. Hoekman, F.
Schreuder and F. Falke, LioniX BV, The Netherlands
The TriPleX™ platform shows very low loss over a large wavelength range (near UV to 2.35 micron). It
can be fabricated on both silicon and Fused Silica, which makes it applicable in a large range of
applications. It is standardized, and available through MPW services.
TuC3.4 2:45 PM - 3:00 PM
Monolithically Integrated Tuneable Photonic Source for the Generation and Modulation of
Millimetre-Wave, G. Kervella, III-V lab, France, M. Chtioui, Thales Air Systems, France, M. Lamponi,
Y. Robert, E. Vinet, D. Make, III-V lab, France, M. Fice, C. Renaud, University College London,UK, G.
Carpintero, Universidad Carlos III de Madrid, Spain and F. Van Dijk, III-V lab, France
A monolithically integrated tuneable photonic source designed for the generation and modulation of
millimetre-wave signals is demonstrated up to 120 GHz. This chip was successfully used in a 200 Mbit/s
wireless short-distance transmission.
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session TuD3: Special Symposium on High Power Diode Lasers and Systems III
Session Chair: Paul Leisher, Rose-Hulman Institute of Technology, USA
TuD3.1 1:30 PM - 2:00 PM (Invited)
Laser Headlights for Automobiles, H. Erdl, BMW, Germany
TuD3.2 2:00 PM - 2:30 PM (Invited)
Mid-Infrared Diode Lasers Between 1800 nm and 2500 nm, S. Hilzensauer, M2K Laser, Germany
We will present results on MBE grown (AlGaIn)(AsSb) quantum well diode lasers between 1.8μm and
2.9μm. We achieved output powers up to 1.3W with peak efficiencies of 32% and optical far fields below
80 degree.
TuD3.3 2:30 PM - 3:00 PM (Invited)
High Peak Power Pulse Generation fromPBC lasers, R. Rosales, V. Kalosha, Institut für
Festkörperphysik, Technische Universität Berlin, T. Kettler, PBC lasers GmbH, K. Posilovic, Institut für
Festkörperphysik, Technische Universität Berlin;PBC laser, M. Miah, D. Bimberg, Institut für
Festkörperphysik, Technische Universität Berlin, J. Pohl, M. Weyers, Ferdinand-Braun-Institut and K.
Lauritsen, PicoQuant GmbH
Picosecond optical pulse generation based on photonic band crystal lasers is a very promising application
of this novel laser type. Mode-locking and direct modulation performance of lasers with different
structure designs will be presented.
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session TuE3: Si Photonics, Polariton Lasers
Session Chair: Karl Unterrainer, TU Vienna, Austria
TuE3.1 1:30 PM - 2:00 PM (Invited)
Hybrid III-V Lasers on Silicon, S. Olivier, S. Malhouitre, C. Kopp, B. Ben Bakir, A. Descos, D. Bordel,
S. Menezo, J. Fedeli, CEA-Leti, France, G. Duan, P. Kaspar, C. Jany, A. Le Liepvre, A. Accard, D.
Make, III-V Lab, France, N. Girard, France, G. Levaufre, A. Shen, P. Charbonnier, F. Mallecot, F.
Lelarge and J. Gentner, III-V Lab, France
We used the molecular wafer bonding technique to develop a hybrid widely tunable, monomode III-V/Si
laser for wavelength division multiplexing, with a tunability over 35 nm and an output power in excess of
3 mW.
TuE3.2 2:00 PM - 2:15 PM
3D Integrated Silicon Photonic External Cavity Laser (SPECL), P. Contu, Boston University, USA,
C. Stagarescu, A. Behfar, BinOptics Corp., USA and J. Klamkin, Boston University, USA
A 3D integrated silicon photonic external cavity laser (SPECL) is presented. The laser comprises an
indium phosphide reflective semiconductor optical amplifier with integrated turning mirror coupled to a
silicon photonic chip through a grating coupler.
TuE3.3 2:15 PM - 2:30 PM
Broadband III-V on Silicon Hybrid Superluminescent LEDs by Quantum Well Intermixing and
Multiple Die Bonding, A. De Groote, INTEC Photonics Research Group - Ghent University, Belgium
Combining quantum well intermixing and multiple die bonding a broadband superluminescent III-V on
silicon LED was realized. Balancing four LEDs with different band gaps resulted in 292nm 3dB
bandwidth and an on-chip power of -8dBm.
TuE3.4 2:30 PM - 2:45 PM
Flexible Four-Channel Silicon-External-Cavity Laser with a Shared Ring Resonator, Y. Kawamura,
H. Yamazaki, Y. Ueda, N. Nunoya and T. Saida, NTT Photonics Laboratories, NTT Corporation, Japan
A four-channel external-cavity laser using one shared ring resonator, which provides a frequency grid,
and four slave ring resonator enables us to select the lasing frequencies of the four subchannels from the
grid frequencies.
TuE3.5 2:45 PM - 3:00 PM
Towards All Monolithic Stabilization of High-Speed Modelocked Semiconductor Lasers, A. Ardey,
E. Sarailou and P. Delfyett, CREOL, University of Central Florida, USA
We present an improved stabilization architecture of a novel orthogonally coupled monolithic colliding
pulse modelocked laser by injection locking it to a hybridly modelocked high-Q external ring cavity with
significant reduction of the phase noise.
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session TuF3: High Q-Factor Microcavities
Session Chair: Hakan Tureci, Princeton University, USA
TuF3.1 1:30 PM - 2:00 PM (Invited)
Ultrahigh-Q Microcavities with Highly Directional Emission, X. Jiang, L. Shao, Q. Gong, Peking
University, Beijing, China and Y. Xiao, Peking University, School of Physics, China
We experimentally realized on-chip deformed microcavities supporting both highly unidirectional
emission and ultrahigh Q factors exceeding 10^8. This type of microcavity holds potential in ultralowthreshold laser and sensitive nanoparticle detection.
TuF3.2 2:00 PM - 2:15 PM
Pump Frequency Noise Coupling into a Microcavity by Thermo-Optic Locking, J. Li, Caltech, USA,
S. Diddams, National Institute of Standards and Technology, USA and K. Vahala, Caltech, USA
Laser-microcavity relative frequency fluctuations caused by thermal locking are studied. The locking of
laser-microcavity detuning causes microcavity temperature fluctuations that transfer pump frequency
noise onto the microcavity modes within the thermal locking bandwidth.
TuF3.3 2:15 PM - 2:30 PM
Selective Excitation of High Radial Order Whispering Gallery Mode in Metallic Grating Coupled
Microsphere, F. Luan, Y. Zhou, B. Gu, Nanyang Technological University, Singapore and X. Yu,
Singapore Institute of Manufacturing Technology, Singapore
A metallic grating coupled whispering gallery mode (WGM) microspherical resonator is investigated. It is
found theoretically that higher radial order WGMs can be selectively excited by phase-match designs of
the grating.
TuF3.4 2:30 PM - 2:45 PM
Nanoparticle Based Plasmonic Enhancement of High Q Optical Microresonators, M. R. Foreman
and F. Vollmer, Max Planck Institute for the Science of Light, Germany
We present an analytic framework based on the extended boundary condition method capable of
describing coupling between a high Q whispering gallery mode resonator and a plasmonic nanoparticle.
Approximate hybrid resonance conditions are derived and the physical consequences of coupling
explored from a biosensing perspective.
TuF3.5 2:45 PM - 3:00 PM
Thermal Nonlinearity Analysis of Toroidal Microcavities, S. Soltani, USC, USA and A. M. Armani,
University of Southern California, USA
The thermally-induced resonance shift produced by absorption of circulating light is studied theoretically
and experimentally. Multiphysics finite element method modeling incorporating thermal and optical
components is performed and verified using toroidal optical cavities.
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session TuG3: All-Optical Signal Processing
Session Chair: Bill Kuo, University of California- San Diego, USA
TuG3.1 1:30 PM - 1:45 PM
Tunable Optical Arbitrary Waveform Generation Based on Time-Delay to Intensity Mapping,
R. Ashrafi, McGill University, Department of Electrical and Computer Engineering, Canada, J. Azaña,
Institut National de la Recherche Scientifique (INRS), Canada and L. Chen, McGill University,
Department of Electrical and Computer Engineering, Canada
We propose and demonstrate through simulations a novel approach for tunable optical arbitrary waveform
generation based on time-delay to intensity mapping using second-order optical integrators implemented
with fiber Bragg gratings.
TuG3.2 1:45 PM - 2:00 PM
Flexible DWDM Grid Manipulation Using Four Wave Mixing-based Time Lenses, K. M. Røge, P.
Guan, H. H. Mulvad, N. Kjøller, M. Galili, T. Morioka and L. K. Oxenløwe, DTU Fotonik, Kongens
Lyngby, Denmark
An experimental demonstration of dense wavelength-division multiplexing (DWDM) grid manipulation
is carried out using two time lenses. A DWDM spectrum is compressed from a 100-GHz to a 28-GHz
grid with error-free performance.
TuG3.3 2:00 PM - 2:30 PM
Wavelength Conversion of a 128 Gbit/s DP-QPSK Signal in a Silicon Polarization Diversity Circuit,
D. Vukovic, Technical University of Denmark, Fotonik department, Denmark, J. Schroeder, Centre for
Ultrahigh bandwidth Devices for Optical Systems, School of, Australia, Y. Ding, Technical University of
Denmark, Fotonik department, Denmark, M. Pelusi, Centre for Ultrahigh bandwidth Devices for Optical
Systems, Australia, L. B. Du, Department of Electrical & Computer Systems Engineering, Monash Unive,
Australia, H. Ou, Technical University of Denmark, Fotonik department, Denmark and C. Peucheret,
FOTON Laboratory, CNRS UMR 6082, ENSSAT, University of Rennes 1, France
Wavelength conversion of a 128 Gbit/s DP-QPSK signal is demonstrated using FWM in a polarization
diversity circuit with silicon nanowires as nonlinear elements. Error-free performances are achieved with
a negligible power penalty.
TuG3.4 2:30 PM - 2:45 PM
All-Optical Reconfigurable Regenerative RZ to NRZ Format Converter Based on a Mach-Zehnder
Interferometer and a Temporal Photonic Integrator, L. Romero Cortés and J. Azaña, Institut National
de la Recherche Scientifique, Canada
A new method for all-optical RZ to NRZ format conversion is presented and numerically demonstrated.
The output eye diagrams feature larger quality-factors than the input diagrams, and more significant
improvements are observed for higher data-rates.
TuG3.5 2:45 PM – 3:00 PM
640 Gbit/s RZ-to-NRZ Format Conversion Based on Optical Phase Filtering, R. Maram, INRS,
University of Quebec, Canada, D. Kong, Beijing University of Posts and Telecommunications, China, M.
Galili, Department of Photonics Engineering, Technical University of Denmark, Denmark, L. Oxenløwe,
Department of Photonics Engineering, Technical University of Denmark, Denmark and J. Azaña, INRSEMT, University of Quebec, Canada
We propose a novel approach for all optical RZ-to-NRZ conversion based on optical phase filtering. The
proposed concept is experimentally validated through format conversion of a 640 Gbit/s coherent RZ
signal to NRZ signal using a simple phase filter implemented by a commercial optical waveshaper.
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session TuH3: Nanophotonic Devices III
Session Chair: Mona Jarrahi, University of California, Los Angeles, USA
TuH3.1 1:30 PM - 2:00 PM (Invited)
Optomechanics Enabled Modulators, Oscillators, and Sensors, S. Bhave, Cornell University, USA
In this talk, I will introduce a method for actuating an optomechanical resonator using electrostatic forces
and sensing of mechanical motion by using the optical intensity modulation at the output of an
optomechanical resonator, integrated into a monolithic system fabricated on a silicon-on-insulator (SOI)
platform.
TuH3.2 2:00 PM - 2:15 PM
On-Chip Wavelength Switch Based on Thermally Tunable Discrete Four-Wave Mixing in a Silicon
Waveguide, M. Pu, Technical University of Denmark, Denmark, Y. Chen, H. Hu and K. Yvind,
Technical Univ. of Denmark, Denmark
An on-chip wavelength switch is proposed based on discrete four-wave mixing in a silicon waveguide.
Switching operation can be realized by thermal tuning the waveguide dispersion. We also discuss optimal
dimension design concerning device performances.
TuH3.3 2:15 PM - 2:30 PM
Silicon Photonic Modulators Based on Epsilon-Near-Zero Indium Tin Oxide Materials, H. Zhao, Y.
Wang, A. Capretti, L. Dal Negro and J. Klamkin, Boston University, USA
We propose a compact silicon photonic modulator based on a slot waveguide with epsilon-near-zero
indium tin oxide materials. The device demonstrates high extinction ratio and low insertion loss over a
wide optical bandwidth.
TuH3.4 2:30 PM - 2:45 PM
Large-Area, High-Q SOI Ring Resonators, M. A. Guillen-Torres, M. Caverley, E. Cretu, N. A. Jaeger
and L. Chrostowski, University of British Columbia, Canada
We demonstrate a large-area, low-loss ring resonator for gyroscopic applications and measured a Q of 1.7
million, the largest value reported to date using standard SOI techniques.
TuH3.5 2:45 PM - 3:00 PM
Moving Boundary and Photoelastic Contributions to Optomechanical Coupling in GaAs
Microcavities, K. Coimbatore Balram, M. Davanco and K. Srinivasan, National Institute of Standards
and Technology, USA
We present simulations and measurements examining moving boundary and photoelastic contributions to
the optomechanical coupling rate g0 in GaAs microdisks, and discuss nanobeam optomechanical crystal
geometries with the potential for enhanced coupling rates.
Plenary
3:30 PM - 5:00 PM
Session TuI4: Plenary Session II
Session Chair: Susumu Noda, Kyoto University, Japan
Room: Vicino Ballroom
TuI4.1
3:30 PM - 4:15 PM (Plenary)
Exploiting Quantum Coherence for New Technologies: Timing, Navigation and Sensors, P. Knight,
Imperial College, UK
The 21st Century has seen the emergence of a networked world, connected by global fibre-optic
communications and mobile phones, with geo-location provided through GPS. All this has changed our
lives more dramatically than at any time since the industrial revolution.
TuI4.2
4:15 PM – 5:00 PM (Plenary)
Cold-Mechanics to Stable-Microwaves: the Future of Optical Microcavity Research, K. Vahala,
California Institute of Technology, USA
Optical-microcavity research has experienced a remarkable decade. Chip-based Q factors are nearly 1
billion while crystalline-device Q factors have reached 100 billion. Applications including cavity
optomechanicx. chens, high-coherence lasers, and stable microwave sources are discussed.
Women in Photonics Reception
5:30 PM - 6:30 PM
Room: Barcino – Gallery I
Session Chair: Dalma Novak, Pharad LLC., USA
5:30 PM – 6:30 PM All attendees and special guests are welcomed.
A special networking event for all members will take place to celebrate the official launch of the IEEE
Photonics Society’s (IPS) Women in Photonics initiative as well as the 20th anniversary of IEEE Women
in Engineering (WIE).
Consistent with the IEEE WIE’s mission of facilitating the global recruitment and retention of women in
engineering and STEM, the goal of the IEEE Photonics Society’s Women in Photonics program is to
create and promote activities that support the participation, engagement and advancement of women in
the photonics and optics community.
At this reception, the achievements and contributions of women members of the IEEE Photonics Society
since its formation, more than four decades ago, will be celebrated. This evening event will offer an
inclusive networking environment for our membership and diversify the spirit of photonics innovation
and collaboration.
Wednesday, October 15, 2014
8:30 AM - 10:30 AM
Session WA1: Emerging Photodetector Technologies
Session Chair: Bora Onat
WA1.1 8:30 AM - 8:45 AM
Spectral and Frequency Response and Signal to Noise Ratio of GeSn-based Heterojunction
Phototransistors, R. Basu, EEE Department, Birla Institute of Technology and Science, India
Heterojunction phototransistors (HPT) using GeSn in base is a potential competitor to that of InGaAsbased HPTs in terms of spectral response, frequency response, gain-bandwidth product, signal-to-noise
ratio and sensitivity in the presence of noise sources.
WA1.2 8:45 AM - 9:00 AM
Flexible Three-Color Silicon Membrane Photodetector Arrays, L. Menon, University of Texas at
Arlington, USA, H. Yang, Semerane, Inc., USA, J. Seo, University of Wisconsin-Madison, USA, S. Wang,
University of Texas at Arlington, USA, Z. Ma, University of Wisconsin-Madison, USA and W. Zhou,
University of Texas at Arlington, USA
We report here design and fabrication of transfer-printed flexible three-color multi-junction 8x8
crystalline silicon membrane photodetector arrays. Based on penetration depth dependent absorption of
different wavelengths, filter-free color detection can be obtained via three junction photocurrent
measurement and imaging fusion processes.
WA1.3 9:00 AM - 9:15 AM
1/f Noise QWIP Infrared Focal Plane Arrays, S. Gunapala, NASA - Jet Propulsion Laboratory, USA
The 1/f noise is a ubiquitous phenomenon and the spectral power density of this fluctuation process is
inversely proportional to the frequency of the signal. In this presentation we will discuss the 1/f noise
measurement of QWIP focal plane array.
WA1.4 9:15 AM - 9:30 AM
Narrow-Band Detector for Underwater Communication System, J. Cheong, University of Sheffield,
UK
We demonstrate that the peak response wavelength in AlInP PIN photodiodes can vary from 480nm500nm due to substrate misorientation. This matches the transmittance range of seawater and would be
suitable for underwater optical communication systems.
WA1.5 9:30 AM - 10:00 AM (Invited)
On-Chip Graphene Optoelectronic Devices for Optical Interconnects, D. Englund, R. Shiue,
Department of Electrical Engineering and Computers Science MIT, USA and X. Gan, Electrical
Engineering Columbia University, USA
Graphene is emerging as an attractive active ma- terial for on-chip opto-electronic devices. We describe
recent progress on hybrid graphene- silicon photonic devices for optical interconnects in the telecom
wavelength region. By coupling graphene to an optical cavity, we demonstrated an efficient electro-optic
modulator that
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session WB1: Chaotic Photonics and Solitons
Session Chair: Roberto Morandotti, EMT/INRS, Canada
WB1.1
8:30 AM - 9:00 AM (Invited)
Complexity Driven Photonics, A. Fratalocchi, KAUST University, Saudi Arabia
Disorder and chaos are ubiquitous phenomena that are mostly unwanted in applications. On the contrary,
they can be exploited to create a new technology. In this talk I willsummarize my research in this field,
discussing chaotic energy harvesting, nonlinear stochastic resonance and complex nanolasers
WB1.2
9:00 AM - 9:15 AM
Frequency Comb Generation Threshold Reduction and Soliton Formation via Input Phase
Modulation, H. Taheri, A. A. Eftekhar and A. Adibi, Georgia Institute of Technology, USA
A theoretical model for microresonator-based frequency comb generation seeded by phase-modulated
input is developed. Numerical simulations based on this model reveal the possibility of combs at reduced
thresholds and deterministic solitons at modest modulation depths.
WB1.3
9:15 AM - 9:30 AM
Dynamics of Bragg Grating Solitons in Grating-Assisted Couplers with Dispersive Reflectivity, S. S.
Chowdhury and J. Atai, The University of Sydney, Australia
Interactions of Bragg grating solitons in a semilinear coupler with dispersive reflectivity are studied.
Various regions of interaction outcomes have been identified. The effect of group velocity mismatch on
interaction dynamics is analyzed.
WB1.4
9:30 AM - 9:45 AM
Dynamical Evolution of Information and Energy in Causal Dispersive Media, A. H. Dorrah and M.
Mojahedi, University of Toronto, Canada
Dynamical exchange of information and energy between an optical pulse and dispersive media supporting
slow or fast light (subluminal or superluminal group velocities) is investigated. By studying this
exchange, we explore the fundamental capabilities and limitations of optical storage devices and fast
signaling applications.
WB1.5
9:45 AM - 10:00 AM
Interactions of Gap Solitons in Coupled Bragg Gratings with Cubic-Quintic Nonlinearity, M. J.
Islam and J. Atai, The University of Sydney, Australia
We investigate the interactions of quiescent gap solitons in coupled Bragg gratings with cubic-quintic
nonlinearity. The dependence of the outcomes of interactions on initial separation and coupling
coefficient is discussed.
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session WC1: Photonic Microwave Generation
Session Chair: Andreas Wiberg
WC1.1 8:30 AM - 9:00 AM (Invited)
Applications of Optoelectronic Oscillators for High Speed Clock recovery and RF Signal
Discrimination, P. Devgan, Air Force Research Laboratory, WPAFB, USA
Photonic systems are preferred solutions for addressing high speed signal processing needs. The
Optoelectronic Oscillator is one photonic technology being investigated. This paper will review
advancements in OEOs for clock recovery and signal discrimination applications.
WC1.2 9:00 AM - 9:15 AM
A Low Phase Noise Dual Loop Optoelectronic Oscillator as a Voltage Controlled Oscillator with
Phase Locked Loop, D. T. Spencer, S. Srinivasan, A. Bluestone, D. Guerra, L. Theogarajan and J. E.
Bowers, University of California Santa Barbara, USA
We demonstrate phase noise improvement in a high frequency 20 GHz optoelectronic oscillator through
dual delay lines and phase locking to a low frequency oven controlled crystal oscillator.
WC1.3 9:15 AM - 9:45 AM (Invited)
Wireless Sub-THz Communication System with High Data RateEnabled by RF Photonics and
Active MMIC Technology, S. Koenig, Infinera Corporation, USA, D. Lopez-Diaz, Lantiq A, Austria, J.
Antes, F. Boes, University of Stuttgart, Germany, R. Henneberger, Radiometer Physics, Germany, A.
Leuther, A. Tessmann, Fraunhofer Institute for Applied Solid-State Physics (IAF), Germany, R.
Schmogrow, Infinera Corporation, USA, D. Hillerkuss, ETH Zurich, Switzerland, R. Palmer, T. Zwick,
C. Koos, W. Freude, Karlsruhe Institute of Technology (KIT), Germany, O. Ambacher, Fraunhofer
Institute for Applied Solid-State Physics (IAF), Germany, J. Leuthold, ETH Zurich, Switzerland and I.
Kallfass, University of Stuttgart, Germany
We demonstrate a wireless sub-THz communication system near 237.5 GHz with one to three carriers and
up to 100 Gbit/s. We use an optical heterodyne I/Q transmitter and a state-of-the-art active I/Q-MMIC at
the receiver.
WC1.4 9:45 AM - 10:00 AM
Radio Transmission and BER Performance of UWB Pulse Generation Based on Directly
Modulated Semiconductor Laser, M. Malekizandi, Q. Le, D. Briggmann, A. Emsia and F. Küppers,
Technische Universitaet Darmstadt, Germany
An optical UWB pulse generation and wireless propagation through UWB antenna is investigated.
Experimental BER results are demonstrated. Shown due to antenna characteristics monocycle pulse is
converted to 3rd order derivative Gaussian after wireless propagation.
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session WD1: Special Symposium: Optoelectronic Devices for Solar Energy Harvesting I
Session Chair: Miguel Modestino, Nanotera-SHINE project at EPFL, Switzerland
WD1.1 8:30 AM - 9:00 AM (Invited)
Routes to Ultrahigh Efficiency Photovoltaic and Photoelectrochemical Devices, H. A. Atwater,
Thomas J. Watson Laboratories & California Institute of Technology, USA, C. Eisler, J. Lloyd, C.
Flowers, S. Darbe, E. Warmann, Thomas J. Watson Laboratories, USA, E. Verlage, K. Fountaine, S. Hu
and N. S. Lewis, California Institute of Technology, USA
We discuss ‘full spectrum’ photovoltaic modules that leverage low-cost III-V compound semiconductor
cells, efficient optics and unconventional fabrication/assembly methods, and discuss advances in
photoelectrochemical water-splitting with high efficiency.
WD1.2 9:00 AM - 9:15 AM (Invited)
The power of Nanowires to Revolutionize Solar Energy, E. Alarcón-Lladó, M. Heiss, E. RussoAverchi, A. Dalmau-Mallorquí, G. Tütüncüoglu, F. Matteini, D. Rüffer, S. Conesa-Boj, O. Demichel and
A. Fontcuberta i Morral, EPFL, Switzerland
There is an expanding interest in finding novel concepts for increasing the efficiency and reduce the cost
in solar cell devices. In this regard, semiconductor nanowires (NWs) provide various paths towards both
goals. In this work we explore the increased device freedom offered by nanowires
WD1.3 9:15 AM - 9:30 AM
Printed High-Efficiency Quadruple-Junction, Four-Terminal Solar Cells and Modules for Full
Spectrum Utilization, X. Sheng, University of Illinois at Urbana-Champaign, USA
We present printed microscale multijunction (MJ) multi-terminal high-efficiency solar cells to overcome
the epi-growth and current-matching limitations of conventional MJ cells. We demonstrate quadruple
junction, four-terminal solar cells with measured efficiencies of 43.9% at concentrations exceeding 1000
suns, and modules with record efficiencies of 36.5%.
WD1.4 9:30 AM - 9:45 AM
Microcrystalline Silicon Solar Cells with Photonic Crystals, Y. Tanaka, K. Ishizaki, M. D. Zoysa, T.
Umeda, Y. Kawamoto, S. Fujita and S. Noda, Dept. of Electronical Science and Engineering, Kyoto
University, Japan
We investigate the enhancement of optical absorption in thin-film microcrystalline-silicon solar cell by
creating multiple resonant modes based on photonic crystal band-edge effect. Experimentally, 1.3 times
increase of photo-current is observed, and theoretically ultimately 9.6% conversion efficiency could be
possible even with only “500nm” microcrystalline-silicon.
WD1.5 9:45 AM - 10:00 AM
Light Management in Tandem Solar Cell with Intermediate Plasmonic Electrode, G. Hossain and
M. Talukder, Bangladesh University of Engineering and Technology, Bangladesh
Tandem solar cell of thin amorphous silicon and microcrystalline silicon layers with intermediate
plasmonic electrode has been proposed. It is found that the intermediate electrode enhances light
absorption as well as solves current matching issues.
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session WE1: Optical Fiber Transmission
Session Chair: Kyunghwan Oh, Yonsei University, Korea
WE1.1 8:30 AM - 9:00 AM (Invited)
Multimode Fiber Transmission at 1310 nm for Data Center Applications, X. Chen, Corning, USA
WE1.2 9:00 AM - 9:30 AM (Invited)
Prospects for Efficient Broadband Optical Amplification in the 1100-1500 nm Wavelength Region,
Y. Jeong, L. A. Vazquez-Zuniga, S. Lee and Y. Kwon, Seoul National University, Korea
The recent advances in fiber-based broadband optical amplification in the 1100-1500 nm wavelength
range and its prospects are overviewed, including the Raman conversion and the parametric process based
on novel optical fibers.
WE1.3 9:30 AM - 9:45 AM
Distributed Raman Amplification in Phase Coherent Transfer of Optical Frequencies Over LongHaul and Metro Fiber Links, G. Bolognini, Consiglio Nazionale delle Ricerche, Italy, D. Calonico, C.
Clivati, INRIM - Istituto Nazionale di Ricerca Metrologica, Italy, S. Faralli, Scuola Superiore Sant'Anna TeCIP Institute, Italy, A. Mura and F. Levi, INRIM - Istituto Nazionale di Ricerca Metrologica, Italy
This paper reports an analysis on distributed Raman amplification (DRA) in phase-coherent opticalfrequency transfer in long-haul and metro fiber links, achieving the transfer of optical frequencies over
305km as well as over a 49km metro link with a fractional instability of 3×10-19 at 1000s.
9:45 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session WF1: Special Symposium on Optomechanics I
Session Chair: Mo Li, University of Minnesota, Twin Cities, USA
WF1.1
8:30 AM - 9:00 AM (Invited)
Silicon Carbide Nano-Optomechanics, Q. Lin, University of Rochester, USA
In this talk, we provide an overview of our recent progress in developing high-quality silicon carbide
micro/nanophotonic devices and exploring nano-optomechanics on this platform.
WF1.2
9:00 AM - 9:30 AM (Invited)
Carbon Integrated Optomechanical Systems, W. H. Pernice, Karlsruhe Institute of Technology,
Germany
I present an integrated optomechanical platform based on polycrystalline diamond thin films. Freestanding resonators with high mechanical quality factors are excited both with gradient optical forces and
through electrostatic actuation.
WF1.3
9:30 AM - 10:00 AM (Invited)
TBD, A. H. Safavi-Naeini, Stanford University, USA
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session WG1: Ultrashort High Intensity Laser
Session Chair: Shoichi Kubodera, University of Miyazaki, Japan
WG1.1 8:30 AM - 9:00 AM (Invited)
Multi-10-TW sub-5-fs Optical Parametric Synthesizer, L. Veisz, D. Rivas, G. Marcus, X. Gu,
D. Cardenas, J. Xu, J. Mikhailova, A. Buck, T. Wittmann, C. M. Sears, Max Planck Institute of Quantum
Optics, Germany, D. Herrmann, Ludwig-Maximilians-Universität, Germany, O. Razskazovskaya,
V. Pervak, Ludwig-Maximilians-Universität, Germany and F. Krausz, Max Planck Institute of Quantum
Optics, Germany
We report on a novel 18-TW peak power light source delivering pulses with 80-mJ energy and 4.5-fs
duration. The system is based on optical parametric synthesizer principle involving multi-color optical
parametric chirped pulse amplification stages.
WG1.3 9:00 AM – 9:30 AM (Invited)
Yb:YAG Thin Disk Mode-Locked Oscillator with High Pulse Energy for Intra-Cavity High
Harmonic Generation, N. Kanda, A. Eilanlou, RIKEN, Japan, T. Imahoko, T. Sumiyoshi, Cyber Laser
Inc., Japan, Y. Nabekawa, RIKEN, Japan, M. Kuwata-Gonokami, The Univ. of Tokyo, Japan and K.
Midorikawa, RIKEN, Japan
We have generated 1-mJ pulses with a pulse duration of 520 fs at a repetition rate of 2.85 MHz in a modelocked oscillator cavity. These pulses can be used for generating high-harmonics in the cavity.
9:30 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session WH1: Micro/Nano Lasers
Session Chair: Yum-Feng Xiao, Peking University, China
WH1.1 8:30 AM - 9:00 AM (Invited)
Electrical Control and Power Enhancement of Microlasers by Selective Pumping, H. Tureci,
Princeton University, USA
WH1.2 9:00 AM - 9:15 AM
Electrically Pumped Metallo-Dielectric Pedestal Nanolasers with High Thermal-Conductivity
Shield, Q. Gu, J. Shane, F. Vallini, J. Smalley, University of California, USA, N. Frateschi, University of
Campinas - UNICAMP, Brazil and Y. Fainman, University of California, USA
We implement amorphous-Al2O3 as a thermally-conductive shield in metallo-dielectric nanolasers, and
demonstrate an electrically pumped device. Joint consideration of various design parameters reveals that
this design allows the laser to dissipate heat through its shield, aiding thermal management in nanoscale
devices.
WH1.3 9:15 AM - 9:30 AM
A cw Room-Temperature Mid-IR Microlaser , M. Hossein-Zadeh, Y. Deng and R. Jain, Center for
High Technology Materials, University of New Mexico, USA
We report the first demonstration of a cw room-temperature mid-IR microlaser. This 2.7-µm opticallypumped (diode, 980 nm) microlaser is based on a high-Q Er-doped ZBLAN spherical microresonator and
has a threshold power of 140 µW
WH1.4 9:30 AM - 9:45 AM
Noise and Dynamics of Stimulated Brillouin Scattering Microresonator Laser Oscillators, W. Loh,
National Institute of Standards and Technology, USA
We experimentally study the noise induced from thermal bistability and the intracavity dynamics of a
1550 nm stimulated Brillouin scattering laser generated from a microresonator.
WH1.5 9:45 AM - 10:00 AM
Anisotropic Stimulated Emission from Aligned CdSe/CdS Dot-in-Rods, Y. GAO, Nanyang
Technological University, Singapore
Anisotropic optical properties of CdSe/CdS dot-in-rods loaded in capillary are demonstrated, suggesting
nanorods’ alignment with a microfluidic approach. Polarized emissions from photoluminescence and
whispering gallery mode lasing show promising applications for lighting and displays.
10:00 AM - 10:30 AM Coffee Break
10:30 AM - 1:30 PM
Session WA2: Midwave Infrared Detectors
Session Chair: Erik Duerr, Massachusetts Institute of Technology, USA
WA2.1 10:30 AM - 10:45 AM
Room Temperature High-Gain InAs/AlAsSbAvalanche Photodiode, W. Sun, University of Virginia,
USA
We report InAs/AlAsSb avalanche photodiodes with depletion regions as thick as 8 µm and room
temperature gain ~ 300.
WA2.2 10:45 AM - 11:00 AM
Planar InAs p-i-n Photodiodes Fabricated Using Ion Implantation, B. S. White, I. Sandall and C.
Tan, University of Sheffield, UK
We present a process for fabricating Planar InAs APDs through Be implantation. Fabrication details are
discussed in addition to current-voltage, responsivity and gain measurements taken from the diodes.
WA2.3 11:00 AM - 11:30 AM (Invited)
InAs APD with Solid State Photomultiplier Characteristics, C. Tan, I. Sandall and B. White, The
University Of Sheffield, UK
InAs electron-avalanche photodiodes (e-APDs) have been demonstrated to have excess noise factor ~1.5
and very high gain-bandwidth product. Recent progress in modelling, array fabrication, high gain
structure and planar APD will be presented.
WA2.4 11:30 AM - 11:45 AM
InAsBi Photodiode Operating in the MWIR, I. Sandall, The Universtiy of Sheffield, UK, F. Bastiman,
B. White, R. Richards, J. David and C. Tan, University of Sheffield, UK
We present results demonstrating an InAsBi photodiode with a photo response beyond 3.6 µm. We
observe photocurrent from the diode up to temperatures of 225 K with a dark current density of 2.6 Acm2.
WA2.5 11:45 AM - 12:00 PM
Enhanced Responsivity by Integration of Interdigitated Electrodes on Ge0.93Sn0.07 Infrared
Photodetectors, T. Pham, B. Conley, L. Huang, W. Du, S. Ghetmiri, A. Mosleh, University of Arkansas,
USA, A. Nazzal, Wilkes University, USA, R. Soref, G. Sun, University of Massachusetts Boston, USA, J.
Margetis, J. Tolle, ASM, USA, H. Naseem and S. Yu, University of Arkansas, USA
The interdigitated electrodes were integrated on Ge0.93Sn0.07/Ge heterostructure photoconductive
detectors. Photoresponse extend to 2.2 µm was achieved, and the enhanced responsivity with reduced
spacing between interdigitated electrodes was observed at room temperature.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session WB2: Parametric Conversion and Fiber Laser
Session Chair: Weili Zhang, Oklahoma State University, USA
WB2.1
10:30 AM - 11:00 AM (Invited)
New States of Light by Third Order Parametric Down Conversion Processes, B. Boulanger, A.
Borne, Université Joseph Fourier, France, C. Felix, CNRS, France, P. Segonds, Université Joseph
Fourier, France, K. Bencheikh and A.J. Levenson, CNRS, France
Third order nonlinear parametric optical interactions performed in bulk crystals or optical fibers lead to
the generation of triple photons, which opens the way for new achievements in quantum optics and
information.
WB2.2
11:00 AM - 11:15 AM
Low-Voltage Optical Phase Modulation by Electric-Field-Induced Phase Transition of KTN Bulk
Crystal, T. Inagaki, NTT Basic Research Laboratories, Japan, T. Imai, J. Miyazu, NTT Photonics
Laboratories, Japan, H. Takesue, NTT Basic Research Laboratories, Japan and J. Kobayashi, NTT
Photonics Laboratories, Japan
We report a low-voltage optical phase modulation that employs the electric-field-induced paraelectricferroelectric phase transition of KTN crystal. We reduced the half-wave voltage to 2.1 Vp-p, which is
very small for a 1-mm-thick bulk crystal.
WB2.3
11:15 AM - 11:45 AM (Invited)
High Power Nanosecond Pulsed Fiber Lasers and Applications, W. Shi, Tianjin University; Tianjin
Institute of Modern Laser & Optics Technology, China and Q. Zhang, Shandong HFB Photonics Co. Ltd.,
China
A high power monolithic nanosecond pulsed fiber laser at 1064nm in MOPA configuration was reported
with more than 300W average power for 475 ns pulses at repetition rate of 100 kHz.
WB2.4
11:45 AM - 12:00 PM
The First Demonstration of Phase and Amplitude Regenerative Multicasting by a Four-Mode
Phase-Sensitive Process, L. Liu, University of California San Diego, USA
We demonstrate the first high-count signal replication accompanied with phase-and-amplitude-noisesqueezing in a four-mode phase-sensitive process. Errorless detection of the phase-modulated information
on a 5.8-GHz-phase-noise broadened carrier has been accomplished over 20-copies in a parametric
multicaster.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session WC2: Microwave Photonics Tutorial
Session Chair: Franklyn Quinlan
WC2.1 10:30 AM - 12:00 PM (Tutorial)
Photonic Advances in Time and Frequency Metrology: Frequency Combs, N. Newbury, NIST, USA
Frequency combs are now the dominate tool in high-precision, high-accuracy optical time and frequency
metrology. I will review their basic behavior, noise properties, design, and discuss a few applications
currently pursued at NIST.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session WD2: Special Symposium: Optoelectronic Devices for Solar Energy Harvesting II
Session Chair: Christophe Moser, EPFL, Switzerland
WD2.1 10:30 AM - 11:00 AM (Invited)
Optics and Photonics for Solar Energy and Buildings at the Advanced Research Projects Agency Energy (ARPA-E), H. M. Branz, U.S. Department of Energy, USA
The Advanced Research Projects Agency - Energy (ARPA-E) of the U.S. Department of Energy funds a
variety of technologies utilizing advanced optics and photonics to split the solar spectrum, redirect and
concentrate photons to energy conversion devices, and also to control cooling infra-red (IR) emissions,
WD2.2 11:00 AM - 11:15 AM (Invited)
Design Principles of Deployable Solar-Hydrogen Generators, M. Modestino, C. Rodriguez, D. Psaltis
and C. Moser, School of Engineering, École Polytechnique Fédérale de Lausanne, Switzerland
The deployment of solar-fuel generators depends both on technological and economic factors. Here we
present physical and cost models of solar-hydrogen generators that elucidate cost-optimum design
parameters for these devices.
WD2.3 11:15 AM - 11:30 AM (Invited)
The Route Towards Low-Cost Solution-Processed High Voc Solar Cells, E. Edri, S. Kirmayer, L.
Barnea-Nehoshtan, S. Mukhopadhyay, M. Kulbak, Y. Tidhar, B. Rybtchinski, D. Cahen and G. Hodes,
Weizmann Institute of Science, Israel
All photovoltaic device efficiencies are limited by the ‘threshold’ process inherent in how photovoltaic
devices work: a photon above a certain energy level is required to excite an electron that will later be
extracted as electrical current.
WD2.4 11:30 AM - 11:45 AM (Invited)
Photon Up-Conversion and Molecular Solar Thermal Energy Storage: New Materials and Devices,
K. Börjesson, A. Lennartsson, V. Gray, D. Dzebo, M. Abrahamsson, B. Albinsson and K. Moth-Poulsen,
Dept. of Chem. & Bio. Eng., Chalmers University of Technology, Sweden
In a future society with limited access to fossil fuels, technologies for efficient on demand delivery of
renewable energy are highly desirable. In this regard, methods that allow for solar energy storage and on
demand solar driven energy generation are particularly relevant since the sun
11:45 AM - 1:30 PM
Lunch Break
10:30 AM - 1:15 PM
Session WE2: Optical Fiber Lasers and Amplifiers
Session Chair: Miro Erkintalo, University of Auckland, New Zealand
WE2.1 10:30 AM - 11:00 AM (Invited)
Crystal Fibers Based Broadband Emissions and Lasers, K. Hsu, D. Jheng, S. Wang, T. Ho, T. Yang,
S. Huang, National Taiwan University, Taiwan, Republic of China, P. S. Yeh, National Taiwan
University of Science and Technology, Taiwan, Republic of China
Doped single crystalline fibers (note: not the photonic crystal fiber) are efficient to emit cw and highbrightness broadband light. Various crystal fibers based broadband emissions and lasers centered from
blue to near infrared will be discussed.
WE2.2 11:00 AM - 11:15 AM
Noise-Eating Amplifier for Repetitive Signals, J. van Howe, Augustana College, USA, R. Maram and J.
Azana, Institut National de la Recherche Scientifique- EMT, Canada
We experimentally show an intensity amplification technique for repetitive signals that is not only noisefree, but reduces pulse-to-pulse intensity fluctuations, ASE noise, and enhances the extinction ratio by the
desired amplification factor to improve signal quality.
WE2.3 11:15 AM - 11:30 AM
Fabrication and Characterization of Multi-Core Photonic Crystal Fibers, Y. Chen, Yanshan
University, China and Y. Wang, Shandong University, China
A novel formulation of rare-earth doped & undoped glass rods was adopted to fabricate up to 19-core
photonic crystal fibers with a crucible-melting and stacking-capillary method at high temperature for
applications of high-power fiber lasers.
WE2.4 11:30 AM - 11:45 AM
Improvement of the experimental methods for the application of liquid to fibers and liquid core
fibers with quantum dots, J. Hwang, Yonsei University, Korea
This study confirms possibility of the application of liquid fiber lasers and optical amplifiers with fiber
lasers integrated into liquid as a gain medium with quantum dots.
11:45 AM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session WF2: Special Symposium on Optomechanics II
Session Chair: Mo Li, University of Minnesota, Twin Cities, USA
WF2.1
10:30 AM - 11:00 AM (Invited)
Photonic Transitions Enabling Novel Silicon Photonic Devices, M. Lipson, Cornell University, USA
WF2.2
11:00 AM - 11:30 AM (Invited)
Triply Resonant Cavity Piezo-Optomechanics at X-Band, H. Tang, Yale University, USA
We demonstrate piezoelectricity enhanced optomechanical systems that simultaneously support
microwave, optical and mechanical resonant modes. The combination of highly sensitive optical readout
and resonantly enhanced piezoelectric actuation enables a microwave oscillator with excellent phase noise
performance, which pushes the micromechanical signal source into microwave X-band.
WF2.3 11:30 AM - 12:00 PM (Invited)
New Directions in Optomechanics: Microfluidic Optomechanics and Brillouin Cooling, T. Carmon,
Technion, Israel
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session WG2: High Power Lasers & Applications
Session Chair: Laszlo Veisz, Max Planck Institute of Quantum Optics, Germany
WG2.1 10:30 AM - 11:00 AM (Invited)
2.0PW, 26.0fs High-Contrast Ti:sapphire CPA Laser System, X. Liang, Shanghai Institute of Optics
and Fine Mechanics, China
WG2.2 11:00 AM - 11:30 AM (Invited)
High power/high energy pulse generation and propagation, J. Diels and L. Arissian, CHTM,
University of New Mexico, USA
Challenges in the generation and propagation of near IR and UV high power and/or high energy laser
pulses are addressed. Achieving long range propagation may require a compromise between short
duration and high energy.
WG2.3 11:30 AM - 11:45 AM
High-Intensity VUV Laser System with OFI Ar2* Amplifier, M. Kaku, N. Deshimaru, M. Katto and
S. Kubodera, University of Miyazaki, Japan
We have constructed the high intensity VUV laser system with an optical-field-induced ionization (OFI)
Ar2* amplifier. The evaluated maximum one-pass gain value of the OFI Ar2* amplifier was 1.17 cm-1.
WG2.4 11:45 AM - 12:00 PM
Recent Performance Results and Progress of the SG-II Upgrade Petawatt Laser Beamline, W. Tao,
Shanghai Institute of Laser Plasma, China
The SG-II upgrade (SG-II-U) Petawatt (PW) laser beamline was tested for its performance recently. A
series of physics experiments including electrons beam generation from a high-Z target irradiated were
carried out, which demonstrated that a focusing intensity of 5*1018W/cm2 could be reached.
12:00 PM - 1:30 PM
Lunch Break
10:30 AM - 1:30 PM
Session WH2: Nanophotonic Light Sources and Detectors
Session Chair: Maiken Mikkelsen, Duke University, USA
WH2.1 10:30 AM - 10:45 AM
Emission Enhancement in Nanowire-Nanoantenna System Fabricated by Nanomanipulation, M.
Ono, E. Kuramochi, NTT Nanophotonics Center, NTT Basic Research Laboratories, Japan, G. Zhang,
NTT Basic Research Laboratories, Japan, H. Sumikura, NTT Nanophotonics Center, NTT Basic Research
Laboratories, Japan, Y. Harada, NTT Basic Research Laboratories, Japan, D. Cox, National Physical
Laboratory, UK and M. Notomi, NTT Nanophotonics Center, NTT Basic Research Laboratories, Japan
We fabricated a coupled system consisting of an InP nanowire and a gold bowtie nanoantenna with a
nanomanipulator installed in a focused ion beam system. The nanoantenna significantly enhanced the
emission from the nanowire.
WH2.2 10:45 AM - 11:00 AM
Low-Cost, Large-Scale, Ordered ZnO nanopillar Arrays for Light Extraction Efficiency
Enhancement in Quantum Dot Light-Emitting Diodes, X. Yang, Nanyang Technological University,
Singapore
We report a QLED with enhanced light outcoupling efficiency by applying a layer of periodic ZnO
nanopillar arrays. The resulting QLED reaches the record external quantum efficiency (EQE) of 9.34% in
green-emitting QLEDs with a similar device structure.
WH2.3 11:00 AM - 11:15 AM
Diode-Pumped, Mechanically-Flexible Organic Lasers Fully Encapsulated with Ultra-Thin Glass
Membranes, C. Foucher, B. Guilhabert, J. Herrnsdorf, N. Laurand and M. Dawson, University of
Strathclyde, UK
Organic semiconductor lasers encapsulated with ultra-thin glass and optically-pumped with a 450nm laser
diode are reported. The lasers are mechanically flexible, have a 290W/cm2 oscillation threshold and their
photo-stability is two orders of magnitude higher than their non-encapsulated counterparts.
WH2.4 11:15 AM - 11:30 AM
Photonic-Crystal-Based InGaAs Photodetector Connected to Load Resistor for Receiver-Less
Llight-to-Voltage Conversion on Chip, K. Nozaki, S. Matsuo, K. Takeda, T. Sato, T. Fujii, E.
Kuramochi and M. Notomi, NTT Nanophotonics Center, Japan
1.7-um-long InGaAs photonic crystal photodetectors connected to a load resistor were demonstrated
towards realizing ultralow-power photoreceivers without electrical amplifiers. A high light-to-voltage
conversion efficiency of 4 kV/W was confirmed with electro-optic probing technique.
WH2.5 11:30 AM - 11:45 AM
Low-Threshold Optical Gain and Lasing of Colloidal Nanoplatelets, Y. Kelestemur, B. Guzelturk,
Bilkent University, Turkey, M. Olutas, Abant Izzet Baysal University, Turkey, S. Delikanli and H. V.
Demir, Bilkent University, Turkey
We systematically studied the gain performance of CdSe-core and CdSe/CdS core/crown NPLs with oneand two-photon optical pumping and achieved the lowest gain threshold of 41µJ/cm2 and 4.48 mJ/cm2
for the green-emitting colloidal nanocrystals, respectively.
WH2.6 11:45 AM - 12:00 PM
Optical Impedance Transformer for Transparent Conducting Electrodes, K. X. Wang, Stanford
University, USA
A fundamental limitation of transparent electrode design is the trade-off between photonic and electronic
performances. We develop the concept of optical impedance transformation, and use it to design
nanostructures for broadband and omnidirectional reduction of optical loss in transparent electrodes
without compromising their electrical performances.
12:00 PM - 1:30 PM
Lunch Break
1:30 PM - 3:30 PM
Session WA3: Interferometric and Temporal Imaging
Session Chair: Sarath Gunapala, NASA – Jet Propulsion Laboratory, USA
WA3.1 1:30 PM - 1:45 PM
In-Situ Measurement of Wafer Camber by a Laser-Feedback Detector, T. Tambosso, Da Yeh
University, Taiwan, R.O.C., S. Donati, University of Pavia, DIII, Italy and R. Horng, Chung Hsing
University, Dept. Precision Eng., Taiwan, Republic of China
Using a laser diode as echo detector of optical reflections from a wafer surface, we demonstrate a simple
and compact optical probe measuring the wafer curvature radius from a few meters to about 10 km.
WA3.2 1:45 PM - 2:15 PM (Invited)
Palm-Size Portable Apparatus of Wide-Field Fourier-Spectroscopic-Imaging in Mid Infrared
Region, I. Ishimaru, Kagawa University, Japan
We proposed the imaging-type 2-dimensional Fourier spectroscopy that is the palmtop-size portable
measurement apparatus and has the strong robustness for mechanical vibrations. And the proposed
method can measure the wide-field 2-dimensional middle-infrared spectroscopic-imaging of radiation
lights emitted from human bodies itself without light sources.
WA3.3 2:15 PM - 2:30 PM
Incoherent-Light Temporal Imaging, B. Li and J. Azaña, Institut National de la Recherche Scientifique
– EMT, Canada
We propose and experimentally demonstrate the first incoherent-light scheme for temporal imaging,
including time-to-frequency mapping, temporal magnification and compression, of high-speed intensity
waveforms.
WA3.4 2:30 PM - 2:45 PM
Novel Temporal Zone Plate Design with Improved Energy Efficiency and Noise Performance, B. Li,
Institut National de la Recherche Scientifique – EMT, Canada, S. Lou, Beijing Jiaotong University,
China and J. Azaña, Institut National de la Recherche Scientifique – EMT, Canada
We propose and experimentally demonstrate a new kind of temporal zone plates, i.e., temporal amplitude
zone plates, providing a 96% improvement in energy efficiency and significantly reducing noise
background as compared with previous temporal intensity zone plates.
2:45 PM - 3:15 PM
Coffee Break
1:30 PM - 3:30 PM
Session WB3: THz Metamaterial and Isolators
Session Chair: Yujie J. Ding, Lehigh University, USA
WB3.1
1:30 PM - 2:00 PM (Invited)
Metamaterial Induced Terahertz Transparency and Absorption, W. Zhang, Oklahoma State
University, USA
Metasurface analogues of electromagnetically induced transparency and absorption are experimentally
observed in near-field coupled subwavelength systems. Engineered with active control mechanisms, the
unique resonances are promising in next-generation chip-scale terahertz photonic devices.
WB3.2
2:00 PM - 2:30 PM (Invited)
A Non-Reciprocal Broadband Terahertz Isolator, A. Mazhorova, INRS-EMT, Canada
We experimentally demonstrate an isolator based on a magnetic non-reciprocal retarder operating with
broadband terahertz pulses. These results stemmed from our recent studies on ferrofluids and ferrites
based devices.
WB3.3 2:30 PM - 2:45 PM
Ultrastable THz Generation Based on Frequency Mixing of Output Beams from Coupled Optical
Parametric Oscillators, P. Hong, R. Wang, X. Zou, Y.J. Ding, Lehigh University, USA, X. Mu, H. Lee,
S. K. Meissner and H. Meissner, Onyx Optics Inc., USA
Efficient THz generation from output of coupled optical parametric oscillators based on stacked
periodically-inverted KTP plates is due to inherent insensitivity of nonlinear conversion to temperature
fluctuation. Enhancement of two orders of magnitude is observed.
WB3.4
2:45 PM - 3:00 PM
Ultrashort Laser Pulse Retrieval Using Single-Shot VAMPIRE, K. Sperlich, Institut für Physik,
Universität Rostock, Germany, B. Seifert, Facultad de Física, Pontificia Universidad Católica de Chile,
Chile and H. Stolz, Institut für Physik, Universität Rostock, Germany
We present first single-shot measurements of a self-referencing technique for measuring the phase and
intensity of ultrashort laser pulses (VAMPIRE). The cross-correlation setup utilizes filter elements to
circumvent relative-phase or direction of time ambiguities.
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session WC3: Photonic Materials and Circuits
Session Chair: D. Guney, Michigan Technological University, USA
WC3.1 1:30 PM - 2:00 PM (Invited)
Transparent Sub-diffraction Optics: Nanoscale Light Confinement Without Metal, Z. Jacob and S.
Jahani, University of Alberta, Canada
We introduce a paradigm shift in light confinement strategy and show that light can be confined beyond
the diffraction limit using transparent artificial media (alldielectric metamaterials). Our approach controls
the optical momentum of evanescent waves – an important electromagnetic property overlooked in
photonic devices.
WC3.2 2:00 PM - 2:30 PM (Invited)
Quantum Photonic Integrated Circuits, A. Fiore, S. Fattah poor, T. Hoang, L. Midolo, F. van Otten, F.
Pagliano, D. Sahin, T. Xia, COBRA Research Institute, Eindhoven University of Technology, J. Beetz, M.
Lermer, S. Hofling, M. Kamp, Technische Physik, Universität Würzburg, A. Gaggero, F. Mattioli and R.
Leoni, Istituto di Fotonica e Nanotecnologie (IFN), CNR, Rome
The building blocks of a new quantum photonic integrated technology will be presented, enabling the onchip generation, processing and detection of single photons for quantum information processing
WC3.3 2:30 PM - 2:45 PM
Design and Fabrication of Guided Mode Resonance Filter for Blue Laser Diode Applications,
M. Byrd and E. Johnson, Clemson University, USA
A guided-mode resonant filter is designed and fabricated to externally lock a GaN blue laser diode. The
structure has polarization selectivity and angular tolerance to help optimize the output from the cavity.
WC3.4 2:45 PM - 3:00 PM
Hybrid InGaN LEDs with Capillary-Bonded MQW Color-Converting Membranes, J. Melo Santos,
B. Jones, PhD Student, Glasgow, UK, P. Schlosser, Researcher at Fraunhofer Centre for Applied
Photonics CAP, Glasgow, UK, J. Herrnsdorf, B. Guilhabert, Researcher at Institute of Photonics,
Glasgow, UK, J. De Jesus, T. Garcia, PhD Student, New York, USA, M. Tamargo, Professor, New York,
USA, J. Hastie, Senior Research Fellow, Glasgow, UK, N. Laurand, Researcher at Institute of Photonics,
Glasgow, UK and M. Dawson, Professor, Glasgow, UK
Hybrid sources consisting of 450nm InGaN LEDs with capillary-bonded micron-thick multi-quantumwell color-converting membranes are reported. Such sources are attractive for visible light
communications and a 540nm-emitting hybrid LED having a 57MHz modulation bandwidth is
demonstrated.
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session WD3: Narrow Linewidth and Hot Topics
Session Chair: Segolene Olivier
WD3.1 1:30 PM - 2:00 PM (Invited)
Narrow-Linewidth Tunable External Cavity Laser for Coherent Communication, A. Daiber,
Emcore Corporation, USA
Narrow-linewidth external cavity lasers have enabled the successful deployment and build out of coherent
optical communication. The strengths of this architecture and robust future are presented.
WD3.2 2:00 PM - 2:15 PM
Characterization of Linewidth of SGDBR Lasers, Y. Yu, J. Zhao, Huazhong Univ.of Sci. & Tech.,
Wuhan National Lab. for optoelectronics, China, T. Huynh, S. Duill, The Rince Institute, Dublin City
University, Ireland, F. Liu, Huazhong Univ.of Sci. & Tech., Wuhan National Lab. for optoelectronics,
China and L. P. Barry, The Rince Institute, Dublin City University, Ireland
The linewidth behaviors of SGDBR lasers as a function of passive sections currents are simulated, and the
detuned-loading effect on the linewidth is demonstrated.Simulated results are in agreement with
experimental results.
WD3.3 2:15 PM - 2:30 PM
Room Temperature Strong Coupling Effects and Polariton Lasing under Electrical Injection,
M. Baten, T. Frost, S. Deshpande, P. Bhattacharya and A. Das, University of Michigan, USA
High temperature electrically pumped polariton lasers using different material systems are demonstrated.
An AlGaAs/AlGaAs quantum well based microcavity with operation at 155K, and a GaN based
microcavity with operation up to 300K are demonstrated.
WD3.4 2:30 PM - 2:45 PM
Suppression of Spatial Hole-Burning and Sub-Picosecond Pulses from Two-Section Quantum
Cascade Lasers, M. A. Talukder, University of Maryland, Baltimore County, USA and C. R. Menyuk,
UMBC, USA
We design a two-section quantum cascade laser that suppresses the growth of continuous waves and
spatial hole-burning and thus helps grow sub-ps pulses from random quantum noise over a broad range of
pump parameters.
WD3.5 2:45 PM - 3:00 PM
FDTD Spectral Characterization for a Partially Slotted, High-Order Laser, F. Bello, A. Abdullaev,
M. Nawrocka, Q. Lu and J. Donegan, Trinity College Dublin, Ireland
We present an in depth analysis of a partially 'slotted' semiconductor laser utilized for single mode
operation exhibiting integrability with photonic devices. The finite-difference-time-domain (FDTD)
method is applied in order to analyze spectral characteristics and particle densities distributed throughout
a partial 37th order grating.
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session WE3: Non-Silica Based Fiber and Components
Session Chair: Sheng-Lung Huang, National Taiwan University, Taiwan
WE3.1 1:30 PM - 2:00 PM (Invited)
Fabrication, Characterization and Applications of Infrared Transparent Chalcogenide Fibers, P.
Lucas, University of Arizona, USA, S. Jiang, AdValue Photonics, USA, G. Colemann, University of
Arizona, USA, T. Luo, AdValue Photonics, USA and Z. Yang, University of Arizona, USA
Chalcogenide glasses have excellent rheological properties and extended infrared transparency down to
25 microns. They are consequently ideally suited for optical fiber fabrication with many applications
ranging from thermal imaging to bio-sensing.
WE3.2 2:00 PM - 2:15 PM
Novel Fiber for Low-Loss Mid-Infrared Transmission, B. Zhang, P. Shum, Nanyang Technological
University, Singapore, W. Yuan, Johns Hopkins University, USA and X. Cheng, JPT Electronics Pte.
Ltd., Singapore
We propose a novel triple-cladding hollow metallic optical fiber, which facilitates low-loss transmission
at mid-infrared region. Our design is realizable with fiber drawing technique.
WE3.3 2:15 PM - 2:30 PM
Three-Wavelength Tm3+:ZBLAN Fiber Laser and its Applications in Water Detection, C. Jia, K.
Ramaswamy, L. Chen, Department of Electrical and Computer Engineering, McGill University, Canada,
A. G. MacLean, N. L. Andrews, J. Saunders, J. A. Barnes, H. Loock, Department of Chemistry, Queen’s
University, Canada and M. Saad, Thorlabs, Inc., USA
We demonstrate a three-wavelength Tm3+:ZBLAN fiber laser emitting simultaneously at 1460 nm, 1503
nm, and 1873 nm and its application in single-pass absorption measurements for detecting and
quantifying water concentration in acetone.
WE3.4 2:30 PM - 2:45 PM
Engineering Metallo Dielectric Structures on Optical Fiber Tips by Self- Assembling Techniques,
M. Pisco, University of Sannio, Italy, F. Galeotti, Institute for Macromolecular Studies, National
Research Council, Italy, R. Parente, G. Quero, Optoelectronic Division - Engineering Department,
University of Sannio, Italy, A. Iadicicco, Department of Engineering, University of Naples “Parthenope”,
Italy, M. Giordano, Institute for polymers, composites and biomaterials, CNR, Italy and A. Cusano,
Optoelectronic Division - Engineering Department, University of Sannio, Italy
We investigate novel fabrication routes to realize regular and well-ordered micro and nanostructures on
optical fiber tips by exploiting self-assembling techniques for sensing applications
2:45 PM - 3:15 PM
Coffee Break
1:30 PM - 3:30 PM
Session WF3: Photonic Crystal and Nanometallic Resonance Devices
Session Chair: Hakan E. Tureci, Princeton University, USA
WF3.1
1:30 PM - 2:00 PM (Invited)
Quantum and Nonlinear Optical Devices Based on Photonic Crystal and Nanometallic Cavities,
J. Vuckovic, Stanford University, USA
Quantum and nonlinear optical effects are studied with InAs/GaAs quantum dots embedded in photonic
crystals or metallic nanoresonators. The applications range from quantum technologies to optical switches
and biosensors. Alternative platforms such as impurities in SiC are considered.
WF3.2
2:00 PM - 2:15 PM
Experimental Demonstration of Adiabatic Light Transfer between Strongly Coupled Photonic
Crystal Nanocavities, R. Konoike, H. Nakagawa, T. Asano, Y. Tanaka and S. Noda, Kyoto University,
Japan
An adiabatic transfer scheme of light between strongly coupled, distant photonic crystal nanocavities is
experimentally demonstrated. Our scheme can be applied to photon transfer which is required in fields
including quantum information processing.
WF3.3
2:15 PM - 2:30 PM
Fast Carrier-Based Nonlinear Dynamics in GaAs Photonic Crystal Cavities at Room Temperature,
R. Bose, J. S. Pelc, C. Santori, S. Vo and R. Beausoleil, Hewlett Packard Labs, USA
We will present our experimental measurements of fast carrier-based dynamics in GaAs photonic crystal
cavities at room temperature for above-band and resonant pumping.
WF3.4
2:30 PM - 2:45 PM
Cavity-Resonator-Integrated Guided-Mode Resonance Filter with Several Grating Lines in
Aperture, K. Kintaka, National Institute of Advanced Industrial Science and Technology, Japan, J.
Inoue, T. Kondo and S. Ura, Kyoto Institute of Technology, Japan
A cavity-resonator-integrated guided-mode resonance filter with 4-µm aperture was fabricated for
operation at 1.54-µm wavelength. A resonance effect was experimentally confirmed in the reflection
spectrum of the fabricated device for the first time.
WF3.5
2:45 PM - 3:00 PM
Use of Coupled Photonic Crystal Nanobeam Cavitiesfor Temporal Integration of Optical Signals,
P. Serafimovich, Image Processing Systems Institute of the Russian Academy of Sciences, Russia
We propose and numerically investigate an all-optical temporal integrator based on a photonic crystal
nanobeam cavity. We show that an array of photonic crystal cavities enables high-order temporal
integration.
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session WG3: Optical Communications Tutorial
Session Chair: Chonjin Xie
WG3.1
1:30 PM – 3:00 PM (Tutorial)
Data-Aided Signal Processing for Coherent Optical Receivers, F. Pittala, Huawei, Germany
In the early implementations of digital signal processing (DSP) for coherent optical receivers, blind
algorithms have been preferred due to their simplicity. However, the use of training sequences can
improve performance significantly and is extensively used in wireless communication systems.
3:00 PM - 3:30 PM
Coffee Break
1:30 PM - 3:30 PM
Session WH3: Quantum Nanophotonics
Session Chair: Ertugrul Cubukcu, University of Pennsylvania, USA
WH3.1 1:30 PM - 2:00 PM (Invited)
On-Demand Optical Properties of Quantum Emitters Using Plasmonic Nanoantennas, M. H.
Mikkelsen, Department of Physics, Duke University, USA
We demonstrate a colloidally synthesized and tunable plasmonic platform for giant fluorescence
enhancement and greatly enhanced spontaneous emission rates of embedded fluorophores. Full-wave
simulations incorporating the nanoscale environment accurately predict the experimentally observed
emission dynamics.
WH3.2 2:00 PM - 2:30 PM (Invited)
Quantum Dot Single Photon Sources: Blinking and Deterministic Device Fabrication, K. Srinivasan,
National Institute of Standards and Technology, USA, M. Davanco, L. Sapienza, National Institute of
Standards and Technology, USA, C. Hellberg, Naval Research Laboratory, USA, S. Ates, National
Institute of Standards and Technology, USA, K. Balram, National Institute of Standards and Technolgoy,
USA, A. Badolato, University of Rochester, USA
We discuss both multiple-time-scale blinking and deterministic device fabrication based on quantum dot
registration through optical positioning, each within the context of creating bright, high efficiency single
photon sources based on self-assembled InAs/GaAs quantum dots.
WH3.3 2:30 PM - 2:45 PM
Room Temperature Electrically Injected In0.4Ga0.6N/GaN Quantum-Dot Visible (?=620 nm)
Single Photon Source, S. Deshpande, T. Frost, A. Hazari and P. Bhattacharya, University of Michigan,
USA
We demonstrate electrically driven single photon emission from MBE grown In0.4Ga0.6N quantum dots
in a GaN p-n diode at room temperature. The single photons have a lifetime ~1ns and g2(0)=0.4.
WH3.4 2:45 PM - 3:00 PM
Thermally Engineered Photonic Crystal Membrane Reflectors Based on Transferred
Nanomembranes on Diamond, S. Liu, D. Zhao, University of Texas at Arlington, USA, J. Seo,
University of Wisconsin-Madison, USA, Y. Liu, University of Texas at Arlington, USA, Z. Ma, University
of Wisconsin-Madison, USA and W. Zhou, University of Texas at Arlington, USA
We report photonic crystal Si membrane reflectors on diamond with improved thermal performance. With
measured 100% reflection, much reduced temperature rise was also observed with high incident power
intensities, making Si membrane reflectors on diamond potential candidates for energy efficiency
nanophotonics devices.
3:00 PM - 3:30 PM
Coffee Break
3:30 PM - 5:00 PM
Session WA4: Optical Receivers and Sensors
Session Chair: Chee-Hing Tan
WA4.1 3:30 PM - 3:45 PM
Performance Improvements of Photonic Lantern Based Coherent Receivers, I. T. Ozdur, Abdullah
Gul University, Turkey, P. Toliver and T. K. Woodward, Applied Communication Sciences, USA
In this work, the signal-to-noise ratio improvement of photonic lantern-based coherent receivers over
single-mode coherent receivers is demonstrated. The signal-to-noise ratio is improved by a factor of 2.8
when other parameters kept constant.
WA4.2 3:45 PM - 4:00 PM
High-Responsivity of InP-Based Photodiodes Integrated with 90o Hybrid by Low Excess Loss MMI
Design over Wide Wavelength Range, T. Kikuchi, H. Yagi, N. Inoue, R. Masuyama, T. Katsuyama, K.
Uesaka, Y. Yoneda and H. Shoji, Sumitomo Electric Industries, LTD., Japan
We demonstrated high-responsivity of InP-based photodiodes integrated with 90o hybrid by low excess
loss multimode interference design over wide wavelength range. These characteristics contribute to
realizing high-sensitivity coherent receivers over their whole operating wavelength range.
WA4.3 4:00 PM - 4:30 PM (Invited)
Heterogeneous Integration: Optical Receivers, B. R. Koch, J. E. Roth, A. Ramaswamy, D. K. Sparacin
and G. A. Fish, Aurrion, Inc. USA
Datacenters are demanding dramatic increases in the volume and density of optical interconnections,
requiring multiple high performance lasers, modulators, and photodiodes in a single module to meet
growing bandwidth needs along with dramatically lower power and cost.
WA4.4 4:30 PM - 4:45 PM
Long-Gauge Distributed Sensor for Monitoring Vibration, M. Comanici, L. Chen, McGill University,
Canada and P. Kung, QPS Photronics, Canada
We propose using an optical fiber cable to monitor distributed vibration changes. The cable connects a
vibration point sensor based on a twin fiber Bragg grating interferometer operating in reflection to its
interrogation unit that locks a narrowband DFB laser to the central interference fringe.
WA4.5 4:45 PM - 5:00 PM
Two-Port Rotation Sensing by an All-Depolarized Interferometric Fiber-Optic Gyroscope, Z. Wang,
D. Zhao, Y. Yang, Y. Li, P. Lu, C. Peng and Z. Li, Peking University, China
All-depolarized interferometric fiber-optic gyroscope has a special feature that the nonreciprocal port is
feasible. By subtracting two results from the reciprocal port and the nonreciprocal port, optical intensity
noise is suppressed.
3:30 PM - 5:00 PM
Session WB4: Magneto-Plasmonics and Nonlinear Imaging
Session Chair: Wei Shi, Tianjin University, China
WB4.1
3:30 PM - 4:00 PM (Invited)
Magnetooptical Intensity Effects in Plasmonic Crystals, I. Akimov, TU Dortmund, Germany
The talk presents an overview on experimental studies of magnetooptical intensity effects in onedimensional plasmonic crystals, which are formed by patterning the noble metal film (gold) with a period
comparable to the surface plasmon-polariton wavelength.
WB4.2
4:00 PM - 4:15 PM
High Average Power Stimulated Raman Scattering in Crystals: Comparison of KGW and
Diamond, A. M. McKay, MQ Photonics Research Centre, Macquarie University, Australia, O. Kitzler,
Macquarie University, Australia, R. Williams, MQ Photonics Research Centre, Macquarie University,
Australia and R. P. Mildren, Macquarie University, Australia
The power and beam quality behavior of second-Stokes KGW and diamond external cavity Raman lasers
at pump powers up to 40 W has been investigated. Severe thermally-induced effects are evident in the
KGW Raman laser at high power levels whereas for diamond these are negligible.
WB4.3
4:15 PM - 4:30 PM
Sensitive Saturable Absorption Response of Large-Size Topological Insulator and Application in
Low-Threshold Solid-State Pulsed Laser, C. Lee, Department of Photonics, NSYSU, Taiwan, Republic
of China
In this work, using topological insulator Bi2Te3, the highly sensitive saturable absorption of few 2.0
W/cm2 and stable Q-switching operation were investigated and achieved in a 1.0 µm Nd:YVO4 laser. In
addition, mode locking operation was observed and discussed.
WB4.4
4:30 PM - 5:00 PM (Invited)
Image Restoration Based on Phase Conjugation in Second-Order Nonlinear Medium, X. Zou, P.
Hong and Y.J. Ding, Department of Electrical and Computer Engineering, Lehigh University, USA
We report progress made on recovery of blurred images caused by atmospheric turbulence using phaseconjugate beam generated by second-order nonlinear process. It is perhaps only scheme for efficiently
recovering image distorted by dynamic atmospheric turbulence.
3:30 PM - 5:00 PM
Session WC4: Novel Photonic Materials
Session Chair: Zubin Jacob, University of Alberta, Canada
WC4.1 3:30 PM - 4:00 PM (Invited)
Vanadium Dioxide for Emerging Photonics, S. Ramanathan, Harvard University, USA
WC4.2 4:00 PM - 4:15 PM
Low-Loss Aluminium Nitride Thin Film for Mid-Infrared Waveguiding, P. Lin, Massachusetts
Institute of Technology, USA, H. Jung, Yale University, USA, L. Kimerling, A. Agarwal, Massachusetts
Institute of Technology, USA and H. Tang, Yale University, USA
Mid-infrared microphotonic devices including straight/bent waveguides and Y-junction beam splitters are
developed on CMOS-compatible AlN-on-silicon platform. A low optical loss of 0.83 dB/cm and efficient
50:50 beam splitting ratio is achieved at ?=2.5 µm.
WC4.3 4:15 PM - 4:30 PM
Chalcogenide Planar Waveguides for Mid-Infrared Applications, D. Choi, P. Ma, Y. Yu, X. Gai, Z.
Yang, S. Madden and B. Luther-Davies, Laser Physics Centre / Australian National University, Australia
We developed chalcogenide planar platform for mid-infrared applications. Careful choice of materials
and control of fabrication are crucial for low-loss waveguide. The devices were demonstrated as chemical
sensor and mid-infrared light source using super-continuum generation.
WC4.4 4:30 PM - 5:00 PM (Invited)
Controlling in-Plane Propagation of Guided Waves Using Metasurfaces, N. Yu, Jet Propulsion
Laboratory, USA
3:30 PM - 5:00 PM
Session WD4: GaN-based + High Power
Session Chair: Roberto Rosales, TU Berlin, Germany
WD4.1 3:30 PM - 4:00 PM (Invited)
High Power Blue and Green Laser Diodes and Their Applications, A. Avramescu, OSRAM Opto
Semiconductors, Inc., Germany
Blue and green laser diodes are gaining momentum in applications requiring visible sources with high
density of light, spectral purity or quick modulation rates. Challenges and advances toward better
efficiency and performance will be presented.
WD4.2 4:00 PM - 4:15 PM
New Type of High Power Pulse Semiconductor Laser Based on Epitaxially-Integrated
AlGaAs/GaAs Thyristor Heterostructure , S. Slipchenko, A. Podoskin, V. Vasileva, A. Rozhkov, N.
Pikhtin, I. Tarasov, Ioffe Institute, Russia, T. Bagaev, M. Zverkov, V. Konyaev, Y. Kurniavko, M.
Ladugin, A. Marmalyuk, A. Padalitsa and V. Simakov, Stel’makh Research and Development Institute,
Russia
We present the latest theoretical and experimental results on nonlinear dynamic of laser-thyristor(890-910
nm). We have demonstrated 4MHz/4.5W high frequency lasing. The energy and amplitude of the control
current density for turning on 28 W peak output optical power were 1.4 nJ and 0.6 A/cm^2
WD4.3 4:15 PM - 4:30 PM
Cost-Effective O-Band High-Power, Low Distortion CWDM Analog Lasers, J. Huang, Emcore
Broadband Division, USA
We develop C-band high-power CWDM analog lasers with excellent distortion linearity performance.
Optical output power, CSO/CTB distortion and chirp are studied. Robust reliability and wavelength
stability are demonstrated.
3:30 PM - 4:30 PM
Session WE4: Fiber Nonlinear Effects and Applications
Session Chair: Pierre Lucas, University of Arizona, USA
WE4.1 3:30 PM - 4:00 PM (Invited)
A Universal All-Fiber Omnipolarizer, P. Bony, M. Guasoni, S. Pitois, P. Morin, D. Sugny, A. Picozzi,
H. Jauslin, G. Millot, Laboratoire Interdisciplinaire Carnot de Bourgogne,France, S. Wabnitz,
Università di Brescia, Italy and J. Fatome, Laboratoire Interdisciplinaire Carnot de Bourgogne UMR
6303 CNRS-UB, France
We report the experimental observation of a self-polarization effect of a light beam in optical fibers
through a counter-propagating four-wave mixing between an incident signal and its backward replica. An
efficient self-polarization of a 40-Gbit/s signal is demonstrated.
WE4.2 4:00 PM - 4:30 PM (Invited)
Temporal Cavity Solitons in Fiber Resonators, M. Erkintalo, J.K. Jang, S.G. Murdoch, S. Coen,
Department of Physics, University of Auckland, New Zealand
In this talk we will review recent advances in the observation and manipulation of temporal cavity
solitons, including temporal tweezing, merging, and dispersive wave emission.
3:30 PM - 5:00 PM
Session WF4: Spectroscopy of Micro/Nano Devices
Session Chair: J. Rosenberg, IBM, USA
WF4.1
3:30 PM - 4:00 PM (Invited)
Resonant Enhancement Mechanisms in Lab-on-Chip Raman Spectroscopy on a Silicon Nitride
Waveguide Platform, R. Baets, A. Dhakal, F. Peyskens, P. Wuytens, Ghent University - Imec, Belgium,
A. Skirtach, Ghent University, Belgium, N. Le Thomas and A. Subramanian, Ghent University - IMEC,
Belgium
Raman spectroscopy gains importance as a label-free detection method for a variety of biomolecules.
While most Raman spectroscopy systems are based on a microscope or a fiber probe, here we discuss the
potential of a lab-on-chip approach based on silicon nitride photonic waveguides.
WF4.2
4:00 PM - 4:15 PM
Coherent Emission from Electrically-Injected InP/InGaAsP Rolled Up Quantum Well Microtubes,
M. Tavakoli Dastjerdi, M. Djavid, P. Bianucci and Z. Mi, McGill University, Canada
We demonstrate coherent emission of electrically-injected rolled up InGaAs/InGaAsP microtubes.
Sequence of optical modes with an energy separation of about 24 meV has been observed.
WF4.3
4:15 PM - 4:30 PM
Capillary-Bonding of Thin LEDs Onto Non-Native Substrates by Transfer-Printing, A. Trindade
and M. Dawson, Institute of Photonics - University of Strathclyde, UK
The integration of arrays of 486nm-emitting micron-size LEDs onto non-native substrates (including
diamond, ultra-thin glass and MQW epitaxial structures) is demonstrated. The device bonding process
relies solely on solvent-assisted capillary adhesion, and precision assembly through transfer printing.
WF4.4
4:30 PM - 4:45 PM
Room-Temperature Electroluminescence from Ge/Ge0.92Sn0.08/Ge Double Heterostructure LED
on Si, Y. Zhou, Microelectronics-Photonics,University of Arkansas, USA
Room temperature electroluminescence (EL) from Ge/Ge0.92Sn0.08/Ge double heterostructure lightemitting diodes has been observed. Spectrum measurements show an emission peak at 0.601eV, which is
attributed to direct bandgap transition.
WF4.5
4:45 PM - 5:00 PM
Emission of Quantum Dots from Waveguides with Chiral Spatially-Modulated Upper Part, S.
Lobanov, Skolkovo Institute of Science and Technology, Russia, T. Weiss, University of Stuttgart,
Germany, N. Gippius, Skolkovo Institute of Science and Technology, Russia, S. Tikhodeev, A. M.
Prokhorov General Physics Institute, Russia, V. Kulakovskii, Institute of Solid State Physics, Russia, K.
Konishi and M. Kuwata-Gonokami, The University of Tokyo, Japan
Emission of randomly distributed quantum dots from chiral photonic crystal structure made of achiral
materials in the absence of external magnetic field at room temperature is theoretically investigated. The
degree of circular polarization of quantum dot's optical emission as high as 99% is achieved.
3:30 PM - 5:00 PM
Session WG4: Spatial Division Multiplexing
Session Chair: Hussam Batshon, TE Subcom, USA
WG4.1 3:30 PM - 4:00 PM
Efficient and Mode Selective Spatial Mode Multiplexer Based on Multi-Plane Light Conversion, G.
Labroille, B. Denolle, P. Jian, CAILabs, France, P. Genevaux, Alcatel-Lucent Bell Labs, France, N.
Treps, Laboratoire Kastler Brossel, UPMC, ENS, CNRS, France and J. Morizur, CAILabs, France
We demonstrate a new spatial mode multiplexer based on Multi-Plane Light Conversion with very low
intrinsic loss (<4.1dB) and high mode selectivity (crosstalk <-23dB). This multiplexer can perform any
mode conversion, and we demonstrate its performance for 6 eigenmodes of a few-mode fiber.
WG4.2 4:00 PM - 4:30 PM (Invited)
Scalability of Few-Mode Fibers for Mode-Division-Multiplexed Systems, P. Sillard, Prysmian Group,
France
We investigate the impact of the increase of the number of LP modes supported by few-mode fibers on
their main characteristics, pointing out the limiting factors of this increase.
WG4.3 4:30 PM - 5:00 PM (Invited)
Self-Homodyne Coherent Detection in Multi-Core Fiber Links, B. J. Puttnam, National Institute of
Information and Communications Technology, Japan
We summarize recent work on self-homodyne detection in multi-core fiber links including transmission,
networking experiments and a comparison with intradyne detection before drawing conclusions about the
feasibility and gaps in current knowledge.
3:30 PM - 5:00 PM
Session WH4: Nanophotonic Waveguides
Session Chair: Kartik Srinivasan, NIST, USA
WH4.1 3:30 PM - 3:45 PM
Focusing Sub-wavelength Grating Coupler, Y. Wang, J. Flueckiger, H. Yun, University of British
Columbia, Canada, R. Bojko, University of Washington, USA, N. A. Jaeger and L. Chrostowski,
University of British Columbia, Canada
We demonstrate sub-wavelength grating couplers for both transverse electric and transverse magnetic
modes. The couplers are designed for silicon-on-insulator wafer with 220 nm-thick silicon and focusing
grating lines have been used to reduce the footprint.
WH4.2 3:45 PM - 4:00 PM
Efficient Method for Long Range Surface Plasmon (LRSPP) Wave Excitation with Si-Based
Grating Couplers, S. Karami, A. Kirk and O. Liboiron-Ladouceur, McGill University, Canada
A new method for LRSPP wave excitation using Si-based grating couplers is proposed. We report a
coupling efficiency of 32 % in design and 16.5 dB loss in measurement from optical fiber to the plasmon
wave.
WH4.3 4:00 PM - 4:15 PM
Broadband One Way Propagation Via Dielectric Waveguides with Unequal Effective Index,
B. Oner, K. Ustun and H. Kurt, TOBB University of Economics and Technology, Turkey
We present an efficient approach for broad band one way propagation of light by parallel and unequal
dielectric waveguides leading different effective phase shifts. Three dimensional numerical simulations
show that 30% operating bandwidth is achieved.
WH4.4 4:15 PM - 4:30 PM
Observation of 4.4 dB Brillouin Gain in a Silicon Photonic Wire, R. Van Laer, Ghent University,
Belgium
We report the first observation of a hypersonic mode of a small-core silicon wire. In particular, we
achieve record 4.4 dB on/off continuous-wave Brillouin gain at 1550 nm. The wire is supported by a tiny
oxide pillar to block the path for external phonon leakage.
WH4.5 4:30 PM - 4:45 PM
A Low-loss, Compact, Broadband, Polarization Insensitive Edge Coupler for Silicon Photonics,
A. Dewanjee, J. N. Caspers, D. F. James and M. Mojahedi, University of Toronto, Canada
We present the design of a broadband, compact, and low loss two level inverse taper edge coupler for
silicon photonics. The polarization maintaining taper has less than 1 dB coupling loss from fiber to silicon
waveguide and efficiently couples to both TE and TM polarizations.
WH4.6 4:45 PM – 5:00 PM
Silicon-on-Insulator (SOI) Nanowire Hot Carrier Electroluminescence, M. du Plessis and P. J.
Venter, University of Pretoria, South Africa
Hot carrier electroluminescence under avalanching conditions in SOI nanowire pn junctions are
investigated. Of interest is the spectral content of the light emission, as well as the light extraction
efficiency. An order of magnitude improvement in light extractuion can be achieved relative to bulk
silicon.
Student Poster Competition
Wednesday 5:30 PM - 6:30 PM
Room: Vicino Ballroom
Session Chair: Thomas Clark, JHU Applied Laboratory, USA
5:30 PM – 6:30 PM
The IEEE Photonics Society is proud to introduce a Student Non-Archived Poster Competition at the
2014 IEEE Photonics Conference to help foster industry-academia interactions and knowledge transfer
covering all areas of optical science and technology and increase student networking opportunities. We
welcome both original and recently published (2013-2014) poster presentations from students in all fields
of photonics.
An independent panel of judges will evaluate the posters during a special session, and financial awards
and merit certificates will be awarded to the best posters. Refreshments will be served during the poster
competition session. The session is a great venue to show off new and recent research, interact with other
students and experts in the photonics field, and possibly win an award that will be presented at the closing
session of the conference.
Thursday, October 16, 2014
8:30 AM - 10:30 AM
Session ThA1: Novel Optical Technologies
Session Chair: Ichiro Ishimaru, Kagawa University, Japan
ThA1.1 8:30 AM - 8:45 AM
Centralised and Portable “Network Forensics” Using Smartphone-Based Diagnostics: Case Study –
the Mapping of Tap Water pH Across Sydney, Australia, M. Hossain, J. Canning, S. Ast, P. Rutledge,
R. Webster, and A. Jamalipour, The University of Sydney, Australia
Using a field portable, smartphone fluorometer for assessing water quality, a pH map of drinking water
around Sydney is obtained. The work demonstrates a new security concept – network forensics - based on
a novel smartgrid approach for the potential detection of water quality disruption.
ThA1.2 8:45 AM - 9:00 AM
A Novel Measurement Set Up for Optical Characterization of CMOS Photodiodes Using
Immersion Oil, A. Kraxner and R. Minixhofer, ams AG, Unterpremstaetten, Austria
In this work a novel measurement procedure is reported which offers the possibility to measure the
intrinsic spectral response of a CMOS photodiode without additional interference effects caused by the
measurement setup.
ThA1.3 9:00 AM - 9:15 AM
Scannable Optofluidic Slit, S. Schuhladen, K. Banerjee, University of Freiburg, IMTEK, Micro-optics,
Germany, M. Stürmer, University of Freiburg, IMTEK, Microactuators, Germany, P. Müller, University
of Freiburg, IMTEK, Micro-optics, Germany, U. Wallrabe, University of Freiburg, IMTEK,
Microactuators, Germany and H. Zappe, University of Freiburg, IMTEK, Micro-optics, Germany
We demonstrate a scannable optofluidic slit based on electrowetting on dielectrics. The device is operated
in full-field or slit mode. Switching times for a 100 µm wide scanning slit are below 120 ms.
ThA1.4 9:15 AM - 9:30 AM
Mid-Infrared Opto-Nanofluidic Slot-Waveguide for Label-free On-Chip Chemical Sensing, p. lin,
Massachusetts Institute of Technology, USA, S. W. Kwok, H. Lin, Harvard University, USA, V. Singh, L.
Kimerling, Massachusetts Institute of Technology, USA, G. Whitesides, Harvard University, USA, D. T.
Tan, Singapore University of Technology and Design, Singapore and A. Agarwal, Massachusetts Institute
of Technology, USA
A mid-infrared sensor for label-free on-chip chemical detection was developed using an engineered
nanofluidic channel consisting of a Si-liquid-Si slot-structure. A sensitivity with 75 times improvement
was achieved compared to conventional evanescent-wave sensing.
ThA1.5 9:30 AM - 10:00 AM (Invited)
Optical Cloaking, G. Barbastathis, Massachusetts Institute of Technology, USA
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session ThB1: Graphene: Carrier Dynamics & Nonlinear Photonics
Session Chair: Andrea Fratalocchi, KAUST, Saudia Arabia
ThB1.1 8:30 AM - 9:00 AM (Invited)
Ultrafast Carrier Dynamics in Graphene Using Intense Terahertz Pulses, S. Tani, Kyoto University,
Japan
We investigated ultrafast dynamics of Dirac electrons under a high electric field in graphene combining
strong THz pulses and ultrafast transient absorption spectroscopy. Comparison with a semi-classical
Boltzmann equation clarifies efficient impact ionization process.
ThB1.2 9:00 AM - 9:15 AM
Spatiotemporal Pattern Recognition with Cascadable Graphene Excitable Lasers, B. J. Shastri, A.
N. Tait, M. A. Nahmias, B. Wu and P. R. Prucnal, Princeton University,USA
We demonstrate a simple photonic spatiotemporal pattern recognition (polychronization) circuit enabled
by cascading two graphene excitable lasers. This technology is a potential candidate for information
processing and computing.
ThB1.3 9:15 AM - 9:30 AM
All-Optical Switching with Cascaded Two-Stage MZIs Using Saturable Absorption Accompanied
by Refractive-Index Change in Graphene, M. Takahashi, H. Kishikawa, N. Goto and S. Yayagiya, The
University of Tokushima, Japan
An all-optical switch using saturable absorption that accompanies refractive-index change in graphene
films is proposed. Effective switching conditions are theoretically derived for arbitrary values of
absorption and refractive-index change.
ThB1.4 9:30 AM - 9:45 AM
Resonant Excitable Switching with Graphene, M. A. Nahmias, Princeton University, USA, B. Shastri,
Princeton University, USA, A. Tait, N. Kunapuli and P. Prucnal, Princeton University, USA
We experimentally demonstrate resonant switching and pulse regeneration using a graphene-based
excitable fiber ring laser and simulate an analogous integrated device structure. Such devices could find
use in pulse regeneration or optical computing.
ThB1.5 9:45 AM - 10:00 AM
Optical Nonlinearities of CVD Fabricated Graphene by Z-Scan Technique, P. Huang, Department of
Photonics, National Sun Yat-Sen University, Taiwan, Republic of China
Optical nonlinearities of single layer graphene were investigated by z-scan method. The two-photon
absorption coefficient ? and nonlinear refractive index n2 are obtained as 0.17 to 5.4 (105 cm/W) and 0.8
to 10 (cm2/GW)82
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session ThC1: Metamaterials and Photonic Crystals
Session Chair: Nanfang Yu
ThC1.1 8:30 AM - 9:00 AM (Invited)
Photonic Graphene: From Conical Diffraction to Topological Insulator, M. Segev, Technion - Israel
Institute of Technology, Israel
ThC1.2 9:00 AM - 9:15 AM
Light Amplification in Metamaterials by Surface Plasmon Polariton Injection, M. Sadatgol and D.
Guney, Michigan Technological University, USA
We propose a new method to amplify light in metamaterial structures. Two auxiliary light sources
generated by surface plasmons constructively interfere with and amplify the signal photons which are
then coupled to free space.
ThC1.3 9:15 AM - 9:30 AM
Dynamic Control of Narrowband Thermal Emission, T. Inoue, M. De Zoysa, T. Asano and S. Noda,
Kyoto University, Japan
We demonstrate dynamic control of narrowband (Q=70) thermal emission with a large change in
emissivity (0.74 to 0.24) and a modulation frequency of ~1MHz, which is four orders of magnitude faster
than in conventional devices.
ThC1.4 9:30 AM - 9:45 AM
Compact Rainbow Trapping and Demultiplexing by Photonic Crystal Waveguides, I. Halil, TOBB
University of Economics and Technology, Turkey
In this study, an all-dielectric GRIN PC with line defects is proposed to use the rainbow trapping to
demultiplexing the light. The propagating beam is demultiplexed by the designed configuration since the
light traps at different locations along the main channel for different operating frequencies.
ThC1.5 9:45 AM - 10:00 AM
Measurement of Ce:YIG Temperature Dependence for Temperature Insensitive Silicon Waveguide
Optical Isolator, Y. Shoji, T. Nemoto and T. Mizumoto, Tokyo Institute of Technology, Meguro-ku,
Japan
The temperature dependences of the refractive index and magneto-optic coefficient of magneto-optic
garnet Ce:YIG are characterized to be 2.5×10&sup-&sup4 K&sup-&sup1 and 13 deg/cm/K, respectively.
The design of a temperature insensitive waveguide optical isolator is proposed.
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:30 AM
Session ThD1: Selection of Best
Session Chair: Peter Smowton, Cardiff University, UK
ThD1.1 8:30 AM - 9:00 AM (Invited)
A Monolithic Electrically Injected InGaN/GaN Disk-in-Nanowire (?=533nm) Laser on (001)
Silicon83, E. Stark, T. Frost, S. Jahangir, S. Deshpande and P. Bhattacharya, University of Michigan,
USA
The first monolithic electrically injected InGaN/GaN disk-in-nanowire green (533nm) edge-emitting laser
grown on (001) silicon is demonstrated. Threshold current density of 1.8kA/cm², spectral linewidth of 9
angstroms, and extrapolated service lifetime of 7000 hours are reported for a 1.5mm cavity length device.
ThD1.2 9:00 AM - 9:30 AM (Invited)
High Power THz Quantum Cascade Lasers Based on Novel Materials and Designs, K. Unterrainer,
TU Wien, Photonics Institute, Austria
We present high performance quantum cascade lasers with a peak output power of 0.94 W. This
development is based on new materials and new symmetric designs for the active region. The devices are
fabricated by a wafer-bonding technique of two symmetric active regions.
9:30 AM - 10:30 AM Coffee Break
8:30 AM - 10:15 AM
Session ThE1: Novel Optical Fibers and Components
Session Chair: Xin Chen, Corning, USA
ThE1.1 8:30 AM - 9:00 AM (Invited)
Novel Brillouin- and Raman-Suppressing Optical Fibers, J. Ballato, Clemson University, USA and P.
Dragic, University of Illinois, USA
This paper describes novel optical fibers employing intrinsically low Brillouin and Raman gain materials.
Such fibers enable continued scaling to higher optical powers critical for their use in modern
communication and defense systems.
ThE1.2 9:00 AM - 9:15 AM
Low-Index Liquid Core Photonic Crystal Fiber Design, J. Park, Yonsei University, Korea, D. Kang, B.
Paulson, T. Nazari and K. Oh, Yonsei University, Korea
Hollow core photonic crystal fiber selectively filled with low-refractive-index liquid at its central hole is
numerically analyzed using the finite element method in terms of effective indices, guided modes,
intensity distribution with varied structural parameters.
ThE1.3 9:15 AM - 9:30 AM
Lab-on-Fiber Technology for Advanced Plasmonic Nano-Optrodes, A. Ricciardi, University of
Sannio, Italy, A. Crescitelli, IMM-CNR, Napoli, Italy, G. Quero, M. Consales, University of Sannio, Italy,
E. Esposito, IMM-CNR, Italy and A. Cusano, University of Sannio, Italy
In this contribution, we report on the versatility of advanced plasmonic Lab-on-Fiber devices directly
realized onto optical fiber tips, as well as their potentialities to work as label-free chemical and biological
sensor.
ThE1.4 9:30 AM - 9:45 AM
Curvature Sensor Based on Long-Period Grating in Dual Concentric Core Fiber, Z. Wu, X. Shao
and P. Shum, Nanyang Technological University, Singapore
We report on a curvature sensor based on a long-period grating in a dual-concentric-core fiber. By
measuring the relative shifting of two adjacent resonant dips, the curvature sensitivity reaches 7.635
nm/m$^{-1}$ .
9:45 AM - 10:15 AM Coffee Break
8:30 AM - 10:30 AM
Session ThF1: Microcavity and Grating Devices
Session Chair: Andrey Matsko, OEWaves, USA
ThF1.1 8:30 AM - 8:45 AM
Interlayer Grating Coupler for Si/SiO2/SiN platform, M. Sodagar, R. Pourabolghasem, A. A. Eftekhar
and A. Adibi, Georgia Tech, USA
We design a low insertion loss (1.9 dB) and wideband (3-dB bandwidth of 50 nm) interlayer grating
coupler for the Si/SiO2/SiN platform. Measured performance of the fabricated device agrees well with the
theoretically predicted results.
ThF1.2 8:45 AM - 9:00 AM
Resonant Reflectors Designed with Zero-Contrast Gratings, R. Magnusson, University of TexasArlington, USA
We present reflectors using resonant gratings with ridges that are matched to an identical material thereby
annulling local reflections, phase changes, and cavity effects. Wideband reflectors with excellent
properties are realized.
ThF1.3 9:00 AM - 9:15 AM
Compact and Broad Band Directional Coupler for Sub-Wavelength Grating SOI Components,
V. Donzella, J. Flueckiger, A. Sherwali, S. Talebi Fard, S. Grist and L. Chrostowski, Department of
Electrical and Computer Engineering, Canada
We present a sub-wavelength grating (SWG) directional coupler, to split light between SWG waveguides.
Fabricated devices have compact design combined with wavelength-flattened response and with low
sensitivity to central wavelength changes and to fabrication errors
ThF1.4 9:15 AM - 9:30 AM
Control of In-plane Loss in Vertical Fabry Perot Cavities with a Grating Mirror, A. Taghizadeh, J.
Mørk and I. Chung, Technical University of Denmark, Denmark
In this paper, we have shown that by using slow Bloch modes of a high-index-contrast grating, it is
possible to control the lateral loss (or quality factor) of a vertical Fabry Perot cavity, which can be used to
improve performance of micro-lasers.
ThF1.5 9:30 AM - 9:45 AM
The Unperturbed Structure in the Coupled Mode Theory of Waveguide Gratings, S. Kamali, E.
Arbabi and L. Goddard, University of Illinois at Urbana-Champagin, USA
We present simulation results demonstrating importance of the chosen unperturbed structure for coupled
mode theory calculations in waveguide gratings. We show that even in simple distributed Bragg
reflectors, using the plain waveguide causes considerable inaccuracies.
ThF1.6 9:45 AM - 10:00 AM
Microring Modulator Using Drop-Port Phase Interference, M. Caverley, H. Jayatilleka, Y. Wang, L.
Chrostowski and N. Jaeger, University of British Columbia, Canada
We present a modulator design where two microring modulators are incorporated into a Mach-Zehnder
interferometer, and show that its extinction ratio and insertion loss can be tuned while staying at a fixed
input wavelength.
10:00 AM - 10:30 AM Coffee Break
8:30 AM - 10:15 AM
Session ThG1: Modulation & Detection II
Session Chair: Benjamin Puttman, NICT
ThG1.1 8:30 AM - 8:45 AM
A Hybrid DPSK-MPPM Technique for High Sensitivity Optical Transmission, A. E. Morra, H.
Shalaby, Egypt-Japan University of Science and Technology (E-JUST), Egypt and Z. Kawasaki, Graduate
School of Engineering, Osaka University, Japan
A new class of optical modulation formats, based on combinations of both MPPM and DPSK modulation
techniques, is proposed. This technique has a better performance than traditional ones and is suitable for
high sensitivity transmission.
ThG1.2 8:45 AM - 9:00 AM
Enhancing Optical Multi-Pulse Pulse Position Modulation Using Hybrid QPSK-Modified MPPM,
H. Selmy, H. Shalaby and Z. Kawazaki, Egypt-Japan University for Science and Technology, Japan
A hybrid quadrature phase shift keying-modified multi-pulse pulse-position modulation scheme is
proposed as a new modulation technique to improve the performance of conventional optical
multi-pulse pulse-position modulation (MPPM) scheme in optical fiber communication systems.
ThG1.3 9:00 AM - 9:15 AM
Closed Form Expressions for SER and Capacity of Shot Noise Limited MIMO-FSO System
Adopting MPPM Over Gamma-Gamma Atmospheric Turbulence Channels, H. Khallaf, H. Shalaby,
Egypt-Japan University of Science and Technology E-JUST, Egypt
Closed form expressions for the symbol-error rate (SER) and capacity of shot-noise limited multiple-input
multiple-output free space optical (MIMO/FSO) communication systems, adopting multipulse pulseposition modulation (MPPM) techniques over gamma-gamma channel model, are derived.
ThG1.4 9:15 AM - 9:30 AM
Can Superluminal Propagation in a Noisy Dispersive Medium Reduce Signal Detection Latency?,
A. H. Dorrah and M. Mojahedi, University of Toronto, Canada
The signal detection latency for superluminal pulses in an inverted medium is calculated and compared to
a vacuum channel. The analysis accounts for both the medium and the detector noise. Accordingly, the
capabilities and limitations of fast light signaling are discussed.
ThG1.5 9:30 AM - 9:45 AM
Electro-Optic Polymer/TiO2 Multilayer Slot Waveguide Modulators, Y. Enami, Kochi University of
Technology, Japan and J. Luo, University of Washington, USA
We report efficient poling of electro-optic polymer and higher mode confinement in hybrid electro-optic
(EO) polymer/TiO2 multilayer slot waveguide modulator.
9:45 AM - 10:15 AM Coffee Break
8:30 AM - 10:30 AM
Session ThH1: Nanophotonic Devices IV
Session Chair: Hilmi Volkan Demir, Bilkent University, Turkey / Nanyang Technological University,
Singapore
ThH1.1 8:30 AM - 8:45 AM
TiO2 Assisted Sensitivity Enhancement in Photosensitive Nanocrystal Skins, A. Yeltik, S. Akhavan,
Bilkent University, Turkey and H. V. Demir, Nanyang Technological University, Singapore / Bilkent
University, Turkey
We propose nanocrystal-based light-sensitive skins with a thin TiO2 layer serving as the electron acceptor
and we demonstrate significant broadband sensitivity enhancement in these photosensors, which operate
with no external bias.
ThH1.2 8:45 AM - 9:00 AM
Advances in Colloidal Quantum Dots Distributed Feedback Lasers Hybridized on Glass
Membranes, B. Guilhabert, C. Foucher, L. McLellan, A. Haughey, Institute of Photonics, University of
Strarhclyde, UK, Y. Gao, Luminous!, Nanyang Technological University, Singapore, J. Herrnsdorf,
Institute of Photonics, University of Strarhclyde, UK, E. Mutlugun, Luminous!, Nanyang Technological
University, Singapore, H. V. Demir, Luminous!, Nanyang Technological University, UK, N. Laurand,
M. D. Dawson, Institute of Photonics, University of Strarhclyde, UK
Mechanically-flexible lasers made of thin-films of colloidal quantum dots on glass membranes are
reported. These ns-pulsed lasers have 0.5mJ/cm2 (100 kW/cm2) thresholds and are wavelength-tunable
across 18 nm. Improvements of CQD-laser materials are also studied.
ThH1.3 9:00 AM - 9:15 AM
Second Harmonic Generation in Quantum Wells Enhanced via Coupling to Metamaterials,
O. Wolf, S. Campione, A. Benz, S. Liu, J. F. Klem, M. B. Sinclair, I. Brener, Sandia National Labs, USA
We experimentally demonstrate efficient second harmonic generation using a metamaterial-coupled III-V
heterostructure at mid-infrared wavelengths. Our approach exploits the large second-order nonlinear
susceptibilities of intersubband transitions and the near-field enhancement and polarization manipulation
flexibility offered by metamaterial resonators.
ThH1.4 9:15 AM - 9:30 AM
Enhanced Sub-Wavelength Focusing by Tilted and Modified Graded Index Medium, E. M. Gayur,
B. B. Oner and H. Kurt, TOBB University of Economics and Technology, Turkey
The inhomogeneous variation of index distribution as graded index (GRIN) medium focuses light without
the curved surfaces. In the current study, we investigate enhanced focusing properties of GRIN medium
with tilted front and back surfaces.
ThH1.5 9:30 AM - 9:45 AM
Characteristics of Emergent Nano-Structures Formed on Diamond by Two-Photon UV Etching,
R. P. Mildren, Macquarie University, Australia
Diamond surfaces etched in the UV at sub-ablation fluencies develop deep sub-wavelength nanostructures
with morphology dependent on the incident polarization. Characterization of the development of etched
patterns provides evidence for bond-selective scission and ejection of carbon species.
9:45 AM - 10:30 AM Coffee Break
Closing Ceremony
Thursday 10:00 AM – 12:00 PM
Room: Vicino Ballroom
Session Chair: Thomas Clark, JHU Applied Laboratory, USA
Post Deadline Session
Best Student Paper and Poster Awards
END OF PROGRAM