1 / 39

Thang Ba Hoang

Investigation of Single Semiconductor Nanowire Heterostructures Using Polarized Imaging Spectroscopy (CdS, GaAs/AlGaAs). Thang Ba Hoang. Department of Physics, University of Cincinnati, Cincinnati, OH. Nanowires for opto-electronic nano-devices. Nanowire high-performance FET.

hoai
Download Presentation

Thang Ba Hoang

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Investigation of Single Semiconductor Nanowire Heterostructures Using Polarized Imaging Spectroscopy (CdS, GaAs/AlGaAs) Thang Ba Hoang Department of Physics, University of Cincinnati, Cincinnati, OH

  2. Nanowires for opto-electronic nano-devices Nanowire high-performance FET Hybrid single-nanowire photonic crystal Nanowire biosensor Single Photon Emitter Nanowire avalanche photodiode

  3. Nanowire related publications (Source: ISI Web of Knowledge - http://isiknowledge.com/)

  4. Content • Introduction • Nanowires and nanowire growth • Micro-photoluminescence techniques for studying single nanowires • Optical properties of single CdS nanowires • Defect and surface related states • Temperature dependent photoluminescence • Photoluminescence imaging of defect states • Optical properties of single core-shell GaAs/AlGaAs nanowires • General photoluminescence properties • Polarization of photoluminescence • Resonant excitation photoluminescence • Polarized resonant excitation • Model for spin relaxation in single nanowires

  5. Nanowires • Nanowires are nanostructures which have diameters ranging from 30 nm to 150 nm, length from 5-20 mm • No significant quantum confinement because wire’s diameter > Bohr exciton diameter • For example: CdS Bohr exciton radius ~2.9 nm GaAs Bohr exciton radius ~10 nm • What make a nanowire different from bulk material? • Huge surface-to-volume ratio: (~108 m-1 for nanowires compared to ~102 m-1 for bulk materials) • strong sensitivity of the excitons to surface states and defects and structural inhomogeneities • Single nanowire measurements are required

  6. Nanowire growth Vapor-Liquid-Solid (VLS) growth GaAs Nanowires Pre-growth AsH3 Ga AsH3 Au 450oC, 30min reactants GaAs 600oC, 10 min desorb surface contaminants and form eutectic alloy. wire diameter: controllable by Au catalyst

  7. core GaAs (650oC, 15 min) shell AlGaAs Core-Shell GaAs/AlGaAs Shell AlGaAs: to increase the quantum efficiency by reducing non-radiative surface recombination Field-Emission Scanning Electron Microscope (FESEM) image: nanowires have tapered shape.

  8. Single nanowire studies GaAs AlGaAs AFM ~40 nm ~80 nm Core-shell GaAs/AlGaAs Nanowires were removed from the growth substrate into solution and deposited onto a silicon substrate

  9. Conduction band (CB) k E ħ~Eg Photoluminescence Valence band (VB) Photoluminescence (PL) A light source (laser) excites electrons from the valence band to the conduction band, leaving holes in valence band. Electrons and holes recombine to emit photons.

  10. e- h+ E Ebin Eg K Excitons • Electron-hole correlation: Exciton • Hydrogen-like bound state of an electron-hole pair • Smaller binding energy (1/1000) • Larger Bohr radius(100 times) • Energy spectrum of an exciton vacuum

  11. Spectrometer L - Lens BS - Beam Splitter DP - Dove Prism 1.5 mm spatial resolution 2D CCD image L CCD Defocusing lens DP Y spatial laser BS Tunable E sample emission energy T=10 K X-Y-Z translation stage Slit-confocal microscopy Experimental setup

  12. PL image rotated PL image from sample Dove prism y Image on CCD camera slit Dove prism to rotate PL image Dove Prism (DP) can be used to rotate image of a nanowire (rotate an image twice the angle that it rotates through ) (Edmund Optics Co.http://www.edmundoptics.com/ )

  13. Single CdS nanowires

  14. CdS nanowires • Majority of nanowires are straight and uniform • Few have significant irregularities SEM • Individual nanowire: ~ 50 – 200 nm in diameter ~ 10 – 15 μm long • Nanowires were removed from the growth substrate into solution and deposited onto a silicon substrate (for single wire study)

  15. Nanowire morphology and optical properties Room temperature Low temperature Irregular-shaped wires Uniform wires Room temperature emission is similar regardless of wire morphology: Near Band Edge emission Low temperature PL differs significantly

  16. A Uniform Wire ~45 – 50 nm Irregular Wire ~100 – 200 nm B B’ A’ 45 nm 150 nm Single nanowire studies We show two representative nanowires: AFM images of the two nanowires: with morphological irregularities straight and uniform

  17. Room-Temp. PL vs Low-Temp. PL Room temperature Low temperature • Low Temperature: the PL properties of the 2 wires differ significantly • Sharp lines are attributed to defect or surface state related emission • Room Temperature: the PL spectra of the 2 wires are alike • Single NBE (Near Band Edge) line emission

  18. Low-Temp. PL imaging Narrow lines occur at specific localized positions along the wires Only NBE emission with occasional small energy variation Excitons localized to particular positions along the wire Compositional/strain fluctuation

  19. NBE Defect-related emission Time-resolved photoluminescence

  20. Time-resolved photoluminescence

  21. Temperature dependence b) - Narrow lines start decreasing in intensity at 30 K and disappear by 90 K - NBE emission becomes the only peak as the temperature increases - Energies of the NBE emission and the localized states follow the band edge as temperature increases - Indicates that localized states are not deep levels but are excitonic This is consistent with time-resolved PL measuring of lifetime!

  22. Single Core/shell nanowires core GaAs (40nm) shell AlGaAs (~20nm)

  23. Core-shell GaAs/AlGaAs Bare (uncoated) GaAs nanowires: low quantum efficiency due to nonradiative surface recombination Undoped MBE-grown GaAs epilayer (PL at 5K) (Heiblum et al. J. Vac. Sci. Tech. B2 233 (1984))

  24. Single nanowire imaging • 2D image and extracted PLs: • Broad spectrum (FWHM ~25 meV) • Emission energy and line-shape are uniform • Lower energy shoulder: defect-related • No evidence of quantum confinement

  25. Temperature dependent PL • PL quenches at T > 140K (activation energy ~17 meV) • Presence of non-radiative centers

  26. Dielectric mismatch “Perfect, infinitely long cylinder” Dielectric mismatch: Excitation: Laser into page (Ruda et al. PRB 72 115308) Emission: PL out of page For GaAs:

  27. photoluminescence laser GaAs/AlGaAs NW: PL Polarization

  28. NW ║ Exciton Non equilibrium spin dynamics Our motivation: dielectric “confinement” of exciton dipole field (D<<l): Exciton densities Photoluminescence intensities N║= N┴ I║ >> I┴ Spin relaxation time ts ? t║ << t┴ We are interested in exciton spin dynamics in single nanowires

  29. core GaAs Tune excitation energy, E Laser , record PL intensity (PLE) Elaser shell AlGaAs AlGaAs AlGaAs GaAs E 2-LO resonances 1-LO GaAs PL hemission hexcitation real space k-space Resonant excitation r

  30. Resonant excitation Clear resonances at 36, 73 and ~133 meV above free exciton energy.

  31. Resonant excitation 1-LO and 2-LO GaAs phonons Resonance at ~133 meV: • Defect-AlGaAs related. or • Bottom of AlGaAs band -Al concentration ~10%, instead of nominal growth concentration 26% How does the polarization depend on excitation energy?

  32. Excitation energy dependent polarization Polarization changes with excitation energy!

  33. Resonant excitation creates non-equilibrium exciton spin distributions • As excitation comes closer to free exciton energy: • Excite parallel: polarization increases • Excite perpendicular: polarization decreases • Wire 2: thermal equilibrium N║ = N┴

  34. ts ts Modeling exciton dynamics Fermi’s golden rule At thermal equilibrium (highest energies) assume:

  35. Spin relaxation time Steady state: Spin relaxation time depends on excitation energy ts ~ 1 - 50 ps tnr ~ 50 ps “Non-Equilibrium Exciton Spin Dynamics in Resonantly Pumped Single Core-Shell GaAs-AlGaAs Nanowires” Thang. B. Hoang, L.V. Titova, J. M. Yarrison-Rice , H. E. Jackson, , A. O. Govorov, Y. Kim, H. J. Joyce, H. H. Tan, C. Jagadish, L. M. Smith Nano Letters 7 588 (2007)

  36. Summary We study optical properties of single CdS and GaAs/AlGaAs Nws: • CdS nanowires: • Room temperature nanowire PL not sensitive to morphological irregularities or defects. • Low temperature (< 20 K) extremely sensitive to such defects. • Spatially resolved PL imaging of defect states • Time-resolved PL shows quantum efficiency can be increased by removing such defects or surface states • Low temperature PL provides quick and non-destructive method for rapidly characterizing NW growth • Exciton spin dynamics from resonantly excited single GaAs-AlGaAs nanowires: • Resonances observed at 1-LO and 2-LO and ~133meV (AlGaAs related) above the PL emission line • Dependence of PL polarization on excitation energies • Spin relaxation time varies from ~1 ps at high energies to ~50 ps near resonance

  37. Rate equations

  38. E Conduction Band Eg k hh Valance Band ESO lh lh (SO) Optical “bright” states - “Bright” states: Δm = ±1 - Ignore the split-off bands

  39. Acknowledgements

More Related