Fundamental studies of excitonic properties in II-VI semiconductors

Urbaszek, Bernhard

January 2001

No description available.

530.41

Fundamental study of growth of (Zn,Cd)Se on GaAs (211)B from hetero-interface to nanostructures

Telfer, Samantha Anne

January 2000

No description available.

530.41

MBE growth and characterisation of ZnSe-based II-VI semiconductors

O'Donnell, Cormac Brendan

January 2000

No description available.

530.41

The fabrication and characterisation of quantum dots, wires and wire net works

Zhang, Qi

January 1996

No description available.

530.41

The effect of fluorine substituents in conjugated polymers

Lӧvenich, Peter Wilfried

January 2001

A new route to a well-defined block copolymer with alternating PEO-solubilising groups and fluorinated distyrylbenzene units was established. The Horner Wittig reaction was used as the polycondensation reaction. The non-fluorinated analogue of this block copolymer was prepared via the Wittig reaction. Both polymers were soluble in chloroform and free-standing films could be cast from solution. The position of the HOMO and LUMO energy levels of these two materials were determined by a combination of cyclic voltammetry, UV photoelectron spectroscopy and UV/Vis absorption spectroscopy. The presence of fluorine substituents on the distyrylbenzene unit had no influence on the HOMO-LUMO band-gap (3.0 eV). However, the position of these two energy levels relative to the vacuum level was shifted to higher energies (0.85 eV shift) in the case of the fluorinated block copolymer. The photoluminescence quantum efficiency of the fluorinated block copolymer was 17%, that of the non-fluorinated block copolymer was 34%. The former was used as the electron conducting layer in a light emitting diode with poly(p-phenylene vinylene) as the emissive layer. The latter was used as the emissive layer in light emitting diodes. Luminances over 2000 cd/m(^2) were observed for devices based on the non-fluorinated block copolymer using indium tin oxide as the anode and aluminium as the cathode. The luminescence efficiency of such devices was as high as 0.5 cd/A, corresponding to an internal quantum efficiency of 1.1%.Furthermore, an oligo(p-phenylene vinylene) was synthesised that contained two terminal fluorinated benzene rings and two central non-fluorinated benzene rings, all connected by vinylene bridges. This material aggregated in a 'brickwall' motif, where each molecule overlaps with two halves of molecules in the row above and below. The structure of this J aggregate is due to aryl-fluoroaryl-interactions and was demonstrated by X-ray crystal structure analysis.

547

Silicon Nanocrystals Embedded In Sio2 For Light Emitting Diode (led) Applications

Kulakci, Mustafa

01 September 2005

In this study, silicon nanocrystals (NC) were synthesized in silicon dioxide matrix by ion implantation followed by high temperature annealing. Annealing temperature and duration were varied to study their effect on the nanocrystal formation and optical properties. Implantation of silicon ions was performed with different energy and dose depending on the oxide thickness on the silicon substrate. Before device fabrication, photoluminescence (PL) measurement was performed for each sample. From PL measurement it was observed that, PL emission depends on nanocrystal size determined by the parameters of implantation and annealing process. The peak position of PL emission was found to shifts toward higher wavelength when the dose of implanted Si increased. Two PL emission bands were observed in most cases. PL emission around 800 nm originated from Si NC in oxide matrix. Other emissions can be attributed to the luminescent defects in oxide or oxide/NC interface. In order to see electroluminescence properties Light Emitting Devices (LED) were fabricated by using metal oxide semiconductor structure, current-voltage (I-V) and electroluminescence (EL) measurements were conducted. I-V results revealed that, current passing through device depends on both implanted Si dose and annealing parameters. Current increases with increasing dose as one might expect due to the increased amount of defects in the matrix. The current however decreases with increasing annealing temperature and duration, which imply that, NC in oxide behave like a well controlled trap level for charge transport. From EL measurements, few differences were observed between EL and PL results. These differences can be attributed to the different excitation and emission mechanisms in PL and EL process. Upon comparision, EL emission was found to be inefficient due to the asymmetric charge injection from substrate and top contact. Peak position of EL emission was blue shifted with respect to PL one, and approached towards PL peak position as applied voltage increased. From the results of the EL measurements, EL emission mechanisms was attributed to tunneling of electron hole pairs from top contact and substrate to NC via oxide barrier.

QC Physics 1-999

Screen and stencil print technologies for industrial N-type silicon solar cells

Edwards, Matthew Bruce, ARC Centre of Excellence in Advanced Silicon Photovoltaics & Photonics, Faculty of Engineering, UNSW

January 2008

To ensure that photovoltaics contributes significantly to future world energy production, the cost per watt of producing solar cells needs to be drastically reduced. The use of n-type silicon wafers in conjunction with industrial print technology has the potential to lower the cost per watt of solar cells. The use of n-type silicon is expected to allow the use of cheaper Cz substrates, without a corresponding loss in device efficiency. Printed metallisation is well utilised by the PV industry due to its low cost, yet there are few examples of its application to n-type solar cells. This thesis explores the use of n-type Cz silicon with printed metallisation and diffusion from printed sources in creating industrially applicable solar cell structures. The thesis begins with an overview of existing n-type solar cell structures, previous printed thick film metallisation research and previous research into printed dopant sources. A study of printed thick-film metallisation for n-type solar cells is then presented, which details the fabrication of boron doped p-type emitters followed by a survey of thick film Ag, Al, and Ag/Al inks for making contact to a p-emitter layer. Drawbacks of the various inks include high contact resistance, low metal conductivity or both. A cofire regime for front and rear contacts is established and an optimal emitter selected. A study of printed dopant pastes is presented, with an objective to achieve selective, heavily doped regions under metal contacts without significantly compromising minority carrier lifetime in solar cells. It is found that heavily doped regions are achievable with both boron and phosphorus, but that only phosphorus paste was capable of post-processing lifetime compatible with good efficiencies. The effect of belt furnace processing on n-type silicon wafers is explored, with large losses in implied voltage observed due to contamination of Si wafers from transition metals present in the belt furnace. Due to exposure to chromium in the belt furnace, no significant advantage in using n-type wafers instead of p-type is observed during the belt furnace processing step. Finally, working solar cells with efficiencies up to 16.1% are fabricated utilising knowledge acquired in the earlier chapters. The solar cells are characterised using several new photoluminescence techniques, including photoluminescence with current extraction to measure the quality of metal contacts. The work in this thesis indicates that n-type printed silicon solar cell technology shows potential for good performance at low cost.

screen printing

n-type silicon

n-type solar cells

stencil printing

screen print dopant sources

photoluminescence

Silicon

Solar cells

Coordinate-targeted optical nanoscopy: molecular photobleaching and imaging of heterostructured nanowires

Oracz, Joanna

08 March 2018

No description available.

530

Physik (PPN621336750)

photobleaching

optical nanoscopy

super-resolution imaging

semiconductor heterostructures

nanowires

photoluminescence

stimulated emission depletion

ground state depletion

microscopy

Synthesis and Luminescence of Zinc Oxide Nanorods-Blended Thiopheno-Organosilicon Polymers

Tyombo, Nolukholo

January 2017

Magister Scientiae - MSc (Chemistry) / The increasing cost of fossil fuel energy production and its implication in environmental pollution and climate change created high demand for alternative and renewable sources of energy. This has led to great interest in research in the field of photovoltaic or solar cells Due to the abundance of sunlight, the technology is sustainable, non-polluting and can be implemented at places where power demand is needed, for example in rural areas. Solar cell devices that have been commercialized are currently based on silicon technology, involving the use of monocrystalline, polycrystalline and amorphous silicon. Although they produce highly efficient solar cells, the cost of Si solar cells is too high. Second generation solar cell materials such as cadmium telluride and third generation materials such as perovskites and organic polymers have been receiving much attention recently. However, they lack the efficiency of Si solar cells. This research proposes the development of high energy conservation photovoltaic cells from novel low-cost organosilicon polymers. The aim was to develop novel highly branched organosilane polymers such as poly(3-hexythiophene), polydi(thien-2-yl)dimethylsilane, poly(3-hexyl- [2,2'] bithiophenyl-5-yl)-dimethyl-thiophen-2yl-silane) as electron donors along with zinc oxide nanorod as the electron acceptor which were able to bring the efficiency of the resultant photovoltaic cell close to that of current Si solar cell. / 2021-08-31

Obtenção de nanocompósitos nanotubos de carbono de parede múltipla e TiO2 e sua caracterização estrutural, óptica e de atividade fotocatalítica

Da Dalt, Silvana

January 2012

Este trabalho teve como objetivo obter nanocompósitos de nanotubos de carbono de paredes múltiplas (NTCPMs) com TiO2, e caracterizá-los quanto a sua estrutura, características ópticas e atividade fotocatalítica. Os nanocompósitos foram obtidos a partir de NTCPMs comerciais (Baytubes®), e dois diferentes TiO2: um comercial (P25) e um obtido na síntese de TiO2 tendo tetra propóxido de titânio (TTP) como precursor. Foram utilizados dois diferentes sistemas líquidos para a obtenção dos nanocompósitos NTCPM-TiO2: um, em pH ácido e outro, em pH alcalino. Os nanocompósitos obtidos a partir do TTP foram posteriormente tratados termicamente a 400 °C, 500 °C, 600 °C e 700 °C para formação de fases cristalinas de TiO2. Os nanocompósitos foram investigados quanto a sua atividade fotocatalítica, empregando-os como catalisadores na degradação do corante orgânico alaranjado de metila, em solução aquosa, sob radiação ultravioleta. Os resultados foram associados a características da estrutura dos nanocompósitos, utilizando técnicas como difração de raios X, microscopia eletrônica de varredura, microscopia eletrônica de transmissão, espectroscopia Raman e espectroscopia por infravermelho e área superficial específica. A caracterização óptica foi obtida por espectroscopia fotoluminescente e espectroscopia por refletância difusa. A análise térmica foi empregada para quantificar a presença de NTCPMs no nanocompósito empregado como catalisador. O desempenho fotocatalítico dos nanocompósitos foi correlacionado com o efeito do pH dos sistemas líquidos empregados na sua obtenção, natureza da interação (química e/ou física) entre nanotubo de carbono e TiO2, fases presentes no TiO2, energia do gap óptico e presença de defeitos estruturais no TiO2. A maior eficiência na fotocatálise foi observada nos nanocompósitos NTCPMs-TiO2 obtidos a partir do TiO2 comercial, e nos obtidos a partir do precursor TTP tratado termicamente a 500 °C, ambos em meio ácido. Estes resultados puderam ser associados às menores energias de transição e nível de defeitos no TiO2 nesses nanocompósitos, quando comparados aos demais. / This study aimed to obtain nanocomposites from multi-walled carbon nanotubes (MWCNTs) with TiO2, and characterize them according to their structure, optical properties and photocatalytic activity. The nanocomposites were obtained from commercial MWCNTs (Baytubes®) and two different types of TiO2: a commercial one (P25) and one obtained by synthesizing TiO2 with titanium tetra propoxide (TTP) as a precursor. Two different fluid systems were used for obtaining the MWCNT-TiO2 nanocomposites: one with acid pH and the other with alkaline pH. The nanocomposites obtained from TTP were subsequently heat treated at 400 °C, 500 °C, 600 °C and 700 °C to form crystalline phases of TiO2. The nanocomposites were investigated for their photocatalytic activity, employing them as catalysts in the degradation of organic methyl orange dye in an aqueous solution under ultraviolet radiation. The results were associated with the characteristics of the nanocomposites’ structure, using techniques such as X-ray diffraction, scanning electron microscopy, transmission electron microscopy, Raman spectroscopy, infrared spectroscopy, and specific surface area. Optical characterization was obtained by photoluminescence spectroscopy and diffuse reflectance spectroscopy. Thermal analysis was used to quantify the presence of MWCNTs in the nanocomposite employed as catalyst. The photocatalytic performance of the nanocomposites were correlated with the effect of the pH of the liquid systems employed for obtaining them, the nature of the interaction (chemical and/or physical) between the carbon nanotube and TiO2, the phases present in the TiO2, the optical energy gap and the presence of structural defects in TiO2. The highest photocatalytic efficiency was observed in the MWCNT-TiO2 nanocomposites obtained from commercial TiO2, and in those obtained from the TTP precursor heat treated at 500 °C, both in an acid medium. These results could be associated with the lower transition energy and level of defects in the TiO2 of these nanocomposites when compared to the other samples.

Nanotubos de carbono

Dióxido de carbono

Nanocompósitos

Fotocatálise

MWCNT-TiO2 nanocomposite

Obtaining

Structural characterization

Photocatalytic activity

Photoluminescence spectroscopy

Structural defects