Growth and Characterization of ZnSe and ZnTe Alloy Nanowires

Li, Zhong

06 December 2012

The objective of this thesis is to explore the synthesis and characterization of high quality binary ZnTe nanowires with great potential for development of optoelectronic devices including high efficiency photovoltaic cells for energy conversion and high sensitivity photodetectors for green fluorescent protein bioimaging at single molecule level. To systematically explore the fabrication process for high quality nanowires, a chemical vapour deposition system was built for nanowire growth. Computational fluid dynamics simulations were used to optimize the reactor and growth parameters. The simulations were validated by experimental measurements. Room temperature photoluminescence measurements showed that high crystal quality with very low defects by single step growth was achieved. This single step growth technique makes a great improvement compared to the reported growth followed by annealing, which achieved equivalent crystal quality. This simplification could be of use in large scale synthesis of nanowires. The simulation results also showed that reactant species concentration is a key factor influencing the growth. A metal-organic chemical vapour deposition system was thus built to independently control reactant concentrations for ZnTe nanowire growth. Temperature-dependent photoluminescence measurements of as-grown ZnTe nanowires showed a strong near band-edge emission. In addition, a deep level oxygen-related band was observed for the first time. From the detailed analysis of thermal quenching of the photoluminescence, it was shown that the deep level emission was partially from the intermediate band of the material. This is of great importance due to the theoretical absorption efficiency that is as high as 63% for intermediate band materials, which is more than two times of that of current single junction concentrators, and few materials possessing this property. Individual ZnTe nanowires, grown after optimization, were patterned and contacted, and their conductivity and photoconductivity were measured at room temperature. A single ZnTe nanowire serving as a photodetector was shown to have the highest reported visible responsivity of 360 A/W (at 530 nm), and a gain of 8,640 (at 3 V bias). The responsivity is roughly 18 times higher than that of silicon avalanche photodiodes. This demonstrates that ZnTe nanowires are strong candidates for single photon detection.

Nanowires

II-VI semiconductors

Synthesis

Characterization

0794

Biology Inspired Nano-materials: Superhydrophobic Surfaces

Victor, Jared J.

07 January 2013

In this research, a low-cost template-based process has been developed to structure the surfaces of polymeric materials rendering them superhydrophobic. This biology-inspired approach was developed using results from the first part of this thesis: the first known detailed study of superhydrophobic aspen leaf surfaces. Aspen leaves, similar to lotus leaves, possess a dual-scale hierarchical surface structure consisting of micro-scale papillae covered by nano-scale wax crystals, and this surface structure was used as a blueprint in the structuring of templates. These distinctive surface features coupled with a hydrophobic surface chemistry is responsible for these leaves’ extreme non-wetting property. Non-wetting is further augmented by the unique high aspect ratio aspen leafstalk geometry. The slender leafstalks offer very little resistance to twisting and bending, which results in significant leaf movement in the slightest breeze, facilitating water droplet roll-off. The structured template surfaces, produced by sand blasting and chemical etching of electrodeposited nanocrystalline nickel sheets, resemble the negative of the superhydrophobic aspen leaf surfaces. Re-usable templates were subsequently employed in a hot embossing technique where they were pressed against softened polymers (polyethylene, polypropylene and polytetrafluoroethylene) thereby transferring their surface structures. The resulting pressed polymer surfaces exhibited features very similar to aspen leaf surfaces. This process increased the water contact angle for all pressed polymers to values above 150 degrees. Additionally, after pressing the water roll-off angle for all polymer surfaces dropped below 5 degrees. The effects of water surfactant concentration, water drop size and temperature on the wetting characteristics of the structured polymers were studied to indicate in which applications these functional surfaces could be most beneficial. Coupling this attractive superhydrophobic surface property with mechanical motion (shaking, bending, or vibrating) could result in superhydrophobic surfaces with superior non-wetting properties suitable for a wide range of applications.

Nano-materials

Superhydrophobic

Polymer Structuring

Electrodeposition

0794

Tungsten Doped Tantalum Oxide Anodes for Electrochemical Disinfection of Wastewater

Holladay, Siobhan

29 November 2012

Tungsten doped tantalum oxide films on titanium substrates were investigated for use as anodes in the electrochemical disinfection of wastewater (measured through e. coli inactivation). A sol-gel method for fabricating these films was developed that allowed for control of both the doping concentration (through volumes of tantalum and tungsten ethoxide added to the solutions), and the thickness (through the number of layers applied). The morphology and composition of these films were investigated using SEM and EDX mapping; the morphology was found to be connected to the fabrication heating procedure. Three different doping concentrations (0%, 8% and 14% tungsten by volume of added metals) were investigated for: 1) electrochemical activity; 2) long-term stability; and 3) disinfection capabilities. The 14% samples demonstrated the highest conductivity (0.06μS/cm), good long-term stability (verified using ICPMS, SEM and EDX analysis) and the best electrochemical activity for removal of e. coli (based on wastewater tests).

Electrochemical disinfection

Doped metal oxide

0794

Tungsten Doped Tantalum Oxide Anodes for Electrochemical Disinfection of Wastewater

Holladay, Siobhan

29 November 2012

Tungsten doped tantalum oxide films on titanium substrates were investigated for use as anodes in the electrochemical disinfection of wastewater (measured through e. coli inactivation). A sol-gel method for fabricating these films was developed that allowed for control of both the doping concentration (through volumes of tantalum and tungsten ethoxide added to the solutions), and the thickness (through the number of layers applied). The morphology and composition of these films were investigated using SEM and EDX mapping; the morphology was found to be connected to the fabrication heating procedure. Three different doping concentrations (0%, 8% and 14% tungsten by volume of added metals) were investigated for: 1) electrochemical activity; 2) long-term stability; and 3) disinfection capabilities. The 14% samples demonstrated the highest conductivity (0.06μS/cm), good long-term stability (verified using ICPMS, SEM and EDX analysis) and the best electrochemical activity for removal of e. coli (based on wastewater tests).

Electrochemical disinfection

Doped metal oxide

0794

Biology Inspired Nano-materials: Superhydrophobic Surfaces

Victor, Jared J.

07 January 2013

In this research, a low-cost template-based process has been developed to structure the surfaces of polymeric materials rendering them superhydrophobic. This biology-inspired approach was developed using results from the first part of this thesis: the first known detailed study of superhydrophobic aspen leaf surfaces. Aspen leaves, similar to lotus leaves, possess a dual-scale hierarchical surface structure consisting of micro-scale papillae covered by nano-scale wax crystals, and this surface structure was used as a blueprint in the structuring of templates. These distinctive surface features coupled with a hydrophobic surface chemistry is responsible for these leaves’ extreme non-wetting property. Non-wetting is further augmented by the unique high aspect ratio aspen leafstalk geometry. The slender leafstalks offer very little resistance to twisting and bending, which results in significant leaf movement in the slightest breeze, facilitating water droplet roll-off. The structured template surfaces, produced by sand blasting and chemical etching of electrodeposited nanocrystalline nickel sheets, resemble the negative of the superhydrophobic aspen leaf surfaces. Re-usable templates were subsequently employed in a hot embossing technique where they were pressed against softened polymers (polyethylene, polypropylene and polytetrafluoroethylene) thereby transferring their surface structures. The resulting pressed polymer surfaces exhibited features very similar to aspen leaf surfaces. This process increased the water contact angle for all pressed polymers to values above 150 degrees. Additionally, after pressing the water roll-off angle for all polymer surfaces dropped below 5 degrees. The effects of water surfactant concentration, water drop size and temperature on the wetting characteristics of the structured polymers were studied to indicate in which applications these functional surfaces could be most beneficial. Coupling this attractive superhydrophobic surface property with mechanical motion (shaking, bending, or vibrating) could result in superhydrophobic surfaces with superior non-wetting properties suitable for a wide range of applications.

Nano-materials

Superhydrophobic

Polymer Structuring

Electrodeposition

0794

Investigating the Interaction of Semiconductor Quantum Dots with in vivo and Cellular Environments to Determine Disposition and Risk

Fischer, Hans Christian

15 February 2011

Nanomaterial toxicity is a major concern and could potentially hamper the progress of biomedical nanotechnology development. Dispelling these concerns requires that the consequences of nanomaterial exposure are evaluated, and the findings will determine whether developmental hurdles can be overcome. This thesis evaluates the both in vivo and in vitro impact of quantum dots (QD , zinc sulphide capped cadmium selenide semiconductor nanocrystals) a fluorescent nanoparticle label with potential as an optical in vivo imaging agent. This work reviews nanoparticle characterization techniques and their importance to biological responses, and surveys QD interactions both in vivo and in vitro. We collected pharmacokinetic and toxicity data by a) quantitatively surveying the in vivo absorption, distribution , metabolism and excretion of QDs, and b) measuring the impacts of QDs on relevant organs (in vivo) and cells (in vitro). Neither of these areas had been explored when this thesis was started. In vivo, intravenous QD dosing in Sprague-Dawley rats showed uptake into reticuloendothelial cells with surface coating dependent kinetics, slow degradation, no excretion detected in feces or urine, and no indications of toxicity. The liver took up the majority of dose after 90 minutes and small amounts of QDs appeared in the spleen, kidney, and bone marrow. After 30 days, the cadmium concentration in the kidneys increased to 3µg/g without a proportional amount of zinc, indicating QD breakdown. In vitro we noted phagocytic capacity comparable to in vivo results, QD breakdown, and a retention of normal macrophage function thereby demonstrating that primary rat liver macrophages (Kupffer cells) are an appropriate in vitro system with which to investigate the cellular responses to quantum dots. Such an in vitro model will facilitate faster evaluation of individual nanotechnologies intended for in vivo use. This dissertation addresses a lack of in vivo background information needed to understand the consequences of QD exposure; though QD fail to demonstrate pharmacokinetics desirable for in vivo imaging agents, they are not toxic. Importantly, we provide in vitro data that will lead to the development of accurate and efficient in vitro primary screening methods that will be central to the further development of biomedical nanotechnologies.

quantum dots

pharmacokinetics

nanoparticle

toxicity

0541

0794

Nanocrystalline Silicon Quantum Dot Light Emitting Diodes Using Metal Oxide Charge Transport Layers

Zhu, Jiayuan

15 November 2013

Silicon-based lighting show promise for display and solid state lighting use. Here we demonstrate a novel thin film light emitting diode device using nanocrystalline silicon quantum dots as an emission layer, and metal oxides as charge transport layers. Sputtering deposition conditions for the nickel and zinc oxides were explored in order to balance deposition rate with minimal roughness, optical absorption, and electrical resistivity. Devices displaying characteristic diode current-voltage behavior were routinely produced, although most showed significant reverse saturation current due to the presence of shunts. Current-voltage behavior of devices made in the same batch showed high repeatability, however variations in device performance was observed between batches while the parameters of synthesis were kept constant. Some devices were observed to emit orange-colored light, consistent with photoluminescence behavior of the silicon quantum dots. Photomultiplier tube measurements shows a turn-on voltage of 5V and an exponential increase in light emission with voltage increase.

Light Emitting Diode

Silicon Quantum Dot

0794

Arrays of Silicon P-i-N Nanowires for Antenna-enhanced and Polarisation Sensitive Detection of Light

Stewart, Corey

28 November 2013

A novel antenna effect is demonstrated in arrays of 500, 200 and 100 silicon nanowires embedded in silicon dioxide. The gratings are analyzed using spectral and polarisation resolved photocurrent microscopy. Resonant enhancements in the electric field and photocurrent response are observed at multiple wavelengths corresponding to coupling of incident radiation into the grating's multiple-scattering electromagnetic modes. The photoresponse retains the sinusoidal polarisation anisotropy expected in single nanowires. The resonances are modeled using electromagnetic scattering theory and show excellent agreement with measurement. An experimental quality factor of Q=10 was measured for the gratings, exceeding that of a single wire, but lower than expected from theory. The difference is ascribed to the finite length of the wires and their termination at ohmic contacts. Strategies to improve Q are discussed, and a grating is presented to resonantly enhance light detection at red, green and blue wavelengths for application as a colour imaging sensor.

Nanowires

Silicon

Optical sensor

0794

0752

Nanocrystalline Silicon Quantum Dot Light Emitting Diodes Using Metal Oxide Charge Transport Layers

Zhu, Jiayuan

15 November 2013

Silicon-based lighting show promise for display and solid state lighting use. Here we demonstrate a novel thin film light emitting diode device using nanocrystalline silicon quantum dots as an emission layer, and metal oxides as charge transport layers. Sputtering deposition conditions for the nickel and zinc oxides were explored in order to balance deposition rate with minimal roughness, optical absorption, and electrical resistivity. Devices displaying characteristic diode current-voltage behavior were routinely produced, although most showed significant reverse saturation current due to the presence of shunts. Current-voltage behavior of devices made in the same batch showed high repeatability, however variations in device performance was observed between batches while the parameters of synthesis were kept constant. Some devices were observed to emit orange-colored light, consistent with photoluminescence behavior of the silicon quantum dots. Photomultiplier tube measurements shows a turn-on voltage of 5V and an exponential increase in light emission with voltage increase.

Light Emitting Diode

Silicon Quantum Dot

0794

Arrays of Silicon P-i-N Nanowires for Antenna-enhanced and Polarisation Sensitive Detection of Light

Stewart, Corey

28 November 2013

A novel antenna effect is demonstrated in arrays of 500, 200 and 100 silicon nanowires embedded in silicon dioxide. The gratings are analyzed using spectral and polarisation resolved photocurrent microscopy. Resonant enhancements in the electric field and photocurrent response are observed at multiple wavelengths corresponding to coupling of incident radiation into the grating's multiple-scattering electromagnetic modes. The photoresponse retains the sinusoidal polarisation anisotropy expected in single nanowires. The resonances are modeled using electromagnetic scattering theory and show excellent agreement with measurement. An experimental quality factor of Q=10 was measured for the gratings, exceeding that of a single wire, but lower than expected from theory. The difference is ascribed to the finite length of the wires and their termination at ohmic contacts. Strategies to improve Q are discussed, and a grating is presented to resonantly enhance light detection at red, green and blue wavelengths for application as a colour imaging sensor.

Nanowires

Silicon

Optical sensor

0794

0752