Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download tdlitho
Document related concepts
Optical coherence tomography wikipedia , lookup
Optical tweezers wikipedia , lookup
Thomas Young (scientist) wikipedia , lookup
Schneider Kreuznach wikipedia , lookup
Nonimaging optics wikipedia , lookup
Surface plasmon resonance microscopy wikipedia , lookup
Magnetic circular dichroism wikipedia , lookup
Diffraction grating wikipedia , lookup
Photon scanning microscopy wikipedia , lookup
Interferometry wikipedia , lookup
Nonlinear optics wikipedia , lookup
Optical aberration wikipedia , lookup
Ultrafast laser spectroscopy wikipedia , lookup
Harold Hopkins (physicist) wikipedia , lookup
Vibrational analysis with scanning probe microscopy wikipedia , lookup
Retroreflector wikipedia , lookup
Astronomical spectroscopy wikipedia , lookup
X-ray fluorescence wikipedia , lookup
Ultraviolet–visible spectroscopy wikipedia , lookup
Transcript
Lithography In the Top-Down Process – New Concepts • Learning Objectives – To identify issues in current photolithography – To quantify the needs of nanomanufacturing – To define improvements in photolithography – To explore new lithography processes – To define the limitations of these new processes in top-down nanomanufacturing What are the limitations of current photolithography processes? • Light sources from traditional mercury vapor lamps have little “deep UV” spectra • Finer feature sizes require shorter wavelength sources • Photoresist must be sensitive to appropriate wavelengths of light • Lenses and optical components have limited numeric aperture Why Shorter Wavelengths? • Minimum Feature Sizes are dictated by the following relationship: F = K (λ/NA) Where F = Feature Size in nM λ = Wavelength (nM) K = Process Constant NA = Numeric Aperture Shorter Wavelength Sources • Replace the mercury vapor lamp an excimer (exciplex) laser source with shorter wavelength emission – ArF – 193 nM – Shorter wavelength than so-called “deep UV” peak of 248nM – F2 Laser – Low output but at 157nM • Matching photoresist that is sensitive to this spectra is also required. • Laser sources under development – 13.5 nM! (extreme UV or EUV range) Numerical Aperture • Light passing through the mask will be subject to diffraction. The numerical aperture of the lens used determines its capability to bring the diffracted pattern into a single point of focus. • NA = n sin θ where n = index of refraction of the media in which the lens is working (air) and θ is the angular spacing between objects making up the image Numerical Aperture (2) • sin θ = 1.22 λ/D where θ is the angular spacing between objects and D = diameter of the lens • A larger diameter lens helps, but is difficult to manufacture • Depth of Field Issues limit the use of larger diameter as a solution Increased NA reduces depth of field Improving the Index of Refraction Improving the Photomask • Sharp edges in photomasks are not well reproduced as feature sizes shrink • Optical proximity correction techniques put borders on corners and edges to correct for this Practice Questions Click once for each question. 1. What limits feature sizes in photolithography? Wavelength of the light source used Numerical aperture of the lens 2. What effect causes blurring in photomasks? Diffraction of the light source 3. What is the limitation that occurs when numerical aperture is increased? Depth of field is decreased Alternative Exposure Methods – Electron Beam Lithography • Use of exposure sources other than UV light has been studied for some time. • An electron beam is exceptionally “narrow”, and does not require a mask • λ=h/P Phase Shift Mask Electron Beam Lithography (2) • E-beam lithography also serves as a tool for mask making • Throughput is not an issue in this case, since the masks are made once, and used many times. • Sub-50 nM feature sizes are possible X-Ray Lithography • Synchrotron radiation sources can be used • Masks use “absorber” materials on a membrane • X-rays pass through the membrane • PMMA photoresists can be used X-Ray Lithography Issues • Spacing, mask dimension, and wavelength are critical So-called “sweet spot” will provide small feature size for a given wavelength exposure and defined mask feature Nano-Imprint Lithography • Concept – To use a “stamp” of precise dimension to create features in resist • Advantages – High Throughput – No issues in diffraction – No secondary emission – Can be carried out in non-vacuum environment Nano-Imprint Lithography (2) • T-NIL (Thermal NanoImprint Lithography) – PMMA resist similar to that used in X-ray lithography is spin coated onto surface – Stamp is pressed into contact with surface – Substrate is heated to glass temperature of resist – Pressure is applied to “stamp” imprint – Substrate cools and stamp can be removed http://www.nilt.com/Default.asp?Acti on=Details&Item=219 UV-Nano Imprint Lithography • UV-NIL (Ultra-violet Nano-Imprint Lithography) – A UV sensitive resist is used – The stamp must be UV-transmissive – UV light is applied through the stamp – Pressure is applied to “stamp” imprint Issues in Nanoimprint Lithography • Alignment of layers can be more difficult than with projection lithography • “Proximity effect” of having large stamp areas near small features may cause uneven feature sizes • Residual layer thickness and profile may vary • Patterned areas may “stick” to stamp AFM Probe Lithography • An atomic force microcscope cantilever writes a pattern in resist – Extremely precise – “Scratching the surface” http://www.pacificnanotech.com/afm -modes_active-modes.html AFM “Dip Pen” Lithography • An atomic force microcscope cantilever writes a pattern in resist – Extremely precise – “Scratching the surface” http://www.pacificnanotech.com/afm -modes_active-modes.html
