Electronic Transport Properties of Nanonstructured Semiconductors: Temperature Dependence and Size Effects

Reynolds, Bryan

28 June 2016

No description available.

Physics

Semiconductor

Nanowire

Size effect

Surface depletion

Dielectric confinement

Quantum confinement

Electron Transport in High Aspect Ratio Semiconductor Nanowires and Metal-Semiconductor Interfaces

Sun, Zhuting

January 2016

No description available.

Condensation

GaAs

Nanowire

Schottky contact

Coulomb screening

surface depletion

dielectric confinement

ELECTRICAL CHARACTERIZATION AND OPTIMIZATION OF GALLIUM ARSENIDE NANOWIRE ENSEMBLE DEVICES

Chia, Andrew

10 1900

<p>III-V nanowire (NW) ensemble devices were fabricated using novel approaches to address key NW optoelectronic issues concerning electrical contacts, doping, surface effects and underlying electrostatics physics.</p> <p>NWs were first embedded in a filling medium, thus achieving low sheet resistance front contacts while preventing shunts. Various filling materials were assessed for porosity, surface roughness and thermal stability, giving Cyclotene as an ideal filing material. Sonication was also introduced as a novel method to achieve perfect planarization.</p> <p>The presence of the Cyclotene also enabled the NWs to be characterized precisely and easily by secondary ion mass spectrometry (SIMS) to give the NW dopant concentration with excellent spatial resolution. Additionally, SIMS characterization demonstrated the ability to characterize the height uniformity of individual segments in a heterostructure NW ensemble.</p> <p>The focus of the work shifted towards surface effects on NW device performance. Therefore, Poisson's equation was solved to provide a comprehensive model of NW surface depletion as a function of interface state density, NW radius and doping density. Underlying physics was examined where surface depletion was found to significantly reduce the conductivity of thin NWs, leading to carrier inversion for some.</p> <p>This model was then applied in conjunction with a transport model to fit current-voltage curves of an AlInP-passivated GaAs NW ensemble device. A 55% decrease in surface state density was achieved upon passivation, corresponding to an impressive four order of magnitude increase in the effective carrier concentration. Additionally, conventional and time-resolved photoluminescence measurements showed intensity and carrier lifetime improvement greater than 20x upon passivation.</p> <p>Finally, the model was extended to describe radial pn junction NWs with surface depletion to give radial energy band profiles for any arbitrary set of NW parameters. Specific cases were analyzed to extract pertinent underlying physics, while the built-in potential was optimized for the design for an optimal device.</p> / Doctor of Philosophy (PhD)

III-V nanowires

photovoltaics

surface passivation

secondary ion mass spectrometry

contact planarization

surface depletion

Engineering Physics

Nanoscience and Nanotechnology

Nanotechnology fabrication

Semiconductor and Optical Materials