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INTRO TO NANOTOOLS at the NanoScience Center University of Copenhagen Jesper Nygård (experimental physics) Plan: MBE, CVD, TEM, SEM, EBL, SPM, AFM, MFM… ”This is experimental physics” …and that’s just the detector… Tools for nanoscience - the top-down approach 1-100 nm Typical menu: • Materials; chemical synthesis, crystal growth • Characterization; electron microscopy, x-ray, scanning probe microscopy • Fabricate your ”nano-lab”; lithography • Interface to macro world; electrical leads, tubes… • Investigate; optical, electrical measurements • Special conditions; high fields, low temperatures wet, … I. MATERIALS FOR NANOELECTRONICS Growing on top of single crystals, preserving the crystal structure 3D, 2D Molecular Beam Epitaxy (MBE) Sources UHV III-V Nanolab, GaAlAs •Layer-by-layer (if lattice matching) •Perfect crystals, very few impurities •Heterostructures, 2D •Optical and electronic applications 1D Molecular Beam Epitaxy (MBE) GaAs nanowires Diameter: 30-100 nm Length: 1 µm III-V Nanolab, GaAlAs Claus B. Sørensen, NBI 1D Chemical Vapour Deposition (CVD) of nanotubes 30,000 kr - Substrate with catalyst nanoparticles - Heat to 900°C - Flow methane gas CH4 - Adsorption, decomposition, solution, saturation, precipitation of nanotubes (root growth) AFM image H. Dai et al, NanoLetters 2002 Hybrid structure: Nanotube grown expitaxially into a semiconductor crystal - Epitaxial overgrowth by MBE (single crystal) - Nanotubes survive being buried - Hybrid electronics from molecular and solid state elements NanoLetters 4, 349 (2004) II. IMAGING NB: Can map the topography, surface potential, magnetic fields, surface chemistry … Magnetic force microscopy (MFM) (tip with magnetic coating) Tracks on harddisk surface Domain structures in thin film micromagnets [D. Weiss et al] Electrostatic force microscopy (EFM) on carbon nanotubes Q ~ -3000 e September 2005 issue Transmission Electron Microscope (TEM) Optical - Å resolution - Transmission, ie only thin slices TEM ”Fullerene peapods” 10 nm Transmission Electron Micrograph Scanning Electron Microscope (SEM) - imaging of 3D structures Au electrodes on SiO2 substrate Silicon nitride bridge III. LITHOGRAPHY - two examples Electron beam lithography (EBL) I. Metallize II. Etch Resolution tens of nm - limited by scattering of electrons (not spot size or wave length) Electron beam lithography (EBL) - examples Side gated quantum point contact etched into two-dimensional electron gas (GaAs/GaAlAs) [P. Utko] Electrodes for contacting individual carbon nanotubes [Nygard et al] Technicality: AFM and alignment marks; EFM Atomic Force Microscopy (AFM) Electrostatic Force Microscopy (EFM) EFM AFM Bockrath et al, NanoLetters (2002) Jespersen et al, NanoLetters (2005) 12 µm 0.1 mm SWNTs Henrik I. Jørgensen, NBI Poster V AFM lithography Eg. by local oxidation of surface with biased AFM tip, line width ~10 nm Quantum point contact in 2DEG (GaAs/GaAlAs) [M. Aagesen] ”Quantum ring” in 2DEG [Enslin et al, ETH] Tools for nanoscience - hands on Typical menu: 9 Materials; chemical synthesis, crystal growth 9Characterization; electron microscopy, scanning probe microscopy 9 Fabricate your ”nano-lab”; lithography 9 Interface to macro world; electrical leads • Investigate; optical, electrical measurements • Special conditions; high fields, low temperatures IV. Electron transport measurements Electrical measurements on individual nanotube molecules sour drain ce Au SiO2 p++ Si gate Vg I V Low temperature transport Dilution refrigerator 20 mK sample T ~ 300 mK sour 2 G (e /h) Current I (nA) 0.3 drain ce Au 0.2 SiO2 p++ Si gate 0.1 0.0 -7.5 -7.0 -6.5 Vg (V) -6.0 -5.5 Gate voltage Vg (V) Vg I Cost for adding one more electron: charging energy: Q2/C ~ e2/C ~ 10 meV >> thermal energy kT = 0.1 meV at 1K Consequence: current is blocked (Coulomb blockade) charging by one electron at a time! V Gold nanoparticle single-electron transistor with carbon nanotube leads i. ii. iii. iv. SiO2 CVD grown nanotubes (Cph) EBL (electron beam lithography) (Cph) AFM imaging and manipulation (Lund) low temperature transport measurements (Lund) Au SiO2 7 nm gold particle (e2/C~60 meV) C. Thelander et al, APL 79, 2106 (2001). Nanoscience - a food chain of ”tools” I. II. III. IV. Materials; crystal growth MBE, CVD Characterization; electron microscopy TEM, SEM scanning probe AFM, EFM, MFM, … Lithography EBL, AFM Measurements; electrical, optical, etc New phenomena, improve understanding, or functionality (ie a new tool) - Hands on experiments, usually not M$ instruments - Very versatile, eg. - SEM for imaging and lithography - AFM for imaging (topography, electrical and magnetic fields, …), lithography, manipulation More to come: 8/9: Lithography, Transmission Electron Microscopy 15/9: Scanning probe microscopy (AFM, STM) and ”why?” (scientific issues) in following sections of the course 10/11: Nanotube electronics Acknowledgements • Nanophysics group, Niels Bohr Institute 2000 2004
