Time-resolved optical studies of excited states in organic photovoltaic diodes

Chow, Philip Chi Yung

January 2014

No description available.

530

Photovoltaic power generation

Transport and device applications of organic photovoltaic materials

Kwok, Kwong Chau

01 January 2010

No description available.

Organic semiconductors

Photovoltaic cells

Theoretical and experimental study of energy selective contacts for hot carrier solar cells and extensions to tandem cells

Jiang, Chu-Wei, School of Photovoltaic Engineering, UNSW

January 2005

Photovoltaics is currently the fastest growing energy source in the world. Increasing the conversion efficiency towards the thermodynamic limits is the trend in research development. ???Third generation??? photovoltaics involves the investigation of ideas that may achieve this goal. Among the third generation concepts, the tandem cell structure has experimentally proven to have conversion efficiencies higher than a standard p-n junction solar cell. The alternative hot carrier solar cell design is one of the most elegant approaches. Energy selective contacts are crucial elements for the operation of hot carrier solar cells. Besides the carrier cooling problem within the absorber, carrier extraction has to be done through a narrow range of energy to minimise the interaction between the hot carriers in the absorber and the cooler carriers in the contacts. Resonant tunnelling through localised states, such as associated with atomic defects or with quantum dots in a dielectric matrix, may provide the required energy selectivity. A new model in studying the properties of resonant tunnelling through defects in an insulator is proposed and investigated. The resulting calculations are simple and useful in obtaining physical insight into the underlying tunneling processes. It is found that defects having a normal distribution along the tunnelling direction do not reduce the transmission coefficient dramatically, which increases the engineering prospects for fabrication. Silicon quantum dots embedded in an oxide provide the required deep energy confinement for room temperature resonant tunnelling operation. A single layer of silicon quantum dots in the centre of an oxide matrix are prepared by RF magnetron sputtering. The method has the advantage of controlling the dot size and the dot spatial position along the tunnelling direction. The presence of these crystalline silicon dots in the oxide is confirmed by high resolution transmission electron microscopy (HRTEM). A negative-differential resistance characteristic has been measured at room temperature on such structures fabricated on an N-type degenerated silicon wafer, a feature that can be explained by the desired resonant tunnelling process. A silicon quantum dot superlattice can be made by stacking multiple layers of silicon quantum dots. A model is proposed for calculating the band structure of such a silicon quantum dot superlattice, with the anisotropic silicon effective mass being taken into account. It suggests a high density of silicon quantum dots in a carbide matrix may provide the bandgap and required mobility for the top cell in the stacks for the recently proposed all-silicon tandem solar cell. The resonant tunnelling modeling and silicon quantum dot experiments developed have demonstrated new results relevant to energy selective contacts for hot carrier solar cells. Building on this work, the modeling study on silicon quantum dots may provide the theoretical basis for bandgap engineering of all-silicon tandem cells.

solar cells

photovoltaic cells

Design of a Static Concentrating Photovoltaic Roof Tile

Dickinson, Michael, Design Studies, College of Fine Arts, UNSW

January 2001

The aim of this document is to investigate through industrial design the potential of a high efficiency photovoltaic concentrator theory. The investigation directs a proposed layout for the design of a device, which specifically addresses the incorporation of the concentrator theory into the design of a photovoltaic ????????roof tile????????. The focus of the investigation has been the integration of theoretical constructs and physical realities. The objective is to facilitate this transition from theory to reality: to contribute to the quest of creating viable manufacturable designs for the generation of clean low cost electrical power. The use of a roof tile as the focus of the incorporating device served two purposes. Number one: it provided a sensible, existing platform, which is under utilised, presented potential and fitted within established building practices. It was not the objective of this thesis to argue that tile integration is the best, only or even the most financially viable direction to pursue; it was one option among many. This brings us to the second purpose; the consideration of existing roofing tiles forced the theory to be applied within set limitations, in particular existing size restrictions. The imposition of a framework to work within highlighted the design issues, which would have to be addressed in the actualisation of the theory. The theory????????s broad strategy for economic viability has been to reduce the actual silicone cell content of panel designs by approximately one third. This is achieved by the use of numerically fewer cells in combination with a concentration method, which does not cost more than the savings gained by the use of fewer cells. This document records the design process undertaken and presents the findings so that further development can be undertaken.

design

photovoltaic

static concentrating

The design and performance of a stand-alone solar and wind powered RTM House

Ortlepp, Angelika

03 April 2007

This research project investigates the viability of using renewable energy sources and passive solar design in Saskatchewan, with its harsh climate, abundant energy resources, and absence of financial incentives for residential renewable energy systems. <p>An experimental Ready-To-Move (RTM) house, using passive solar design and stand-alone solar and wind power with gas generator backup, was designed and built and has been tested for a one year period from January to December, 2006.<p>The design methodology was based on well established design procedures for passive solar homes and renewable energy systems that are documented in the literature. A data collection system was used to record solar and wind charging currents, and battery status and temperature data was recorded on a daily basis. Average household loads were estimated from this data. <p>For 2006, the power generation of the solar array was 990 kWh, which was better than the expected output of 927 kWh. However, the wind generator produced only 475 kWh, which was substantially less the expected output of 1430 kWh. Average wind speeds were lower than the normal for 2006 and power production was less than the manufacturers projections for the specified wind speeds. Financial analysis showed that the lack of incentives and net metering made an off-grid system economically feasible only in remote locations where the cost of grid connection is over $20,000.

energy efficient design

photovoltaic

Photovoltaic Process Development and innovative Techniques

Ismail, Furrukh

January 2011

Photovoltaic processing is one of the processes that have significance in semiconductor process line. It is complicated due to the no. of elements involved that directly or indirectly affect the processing and final yield. So mathematically or empirically we can’t say assertively about the results specially related with diffusion, antireflective coating and impurity poisoning. Here I have experimented and collected data on the mono-crystal silicon wafers with varying properties and outputs. Then by using neural network with available experimental data output required can be estimated which is further tested by the test data for authenticity. One can say that it’s a kind of process simulation with varying input of raw wafers to get desired yield of photovoltaic mono-crystal cells.

Photovoltaic

Mono-crystal

Diffusion

The design and performance of a stand-alone solar and wind powered RTM House

Ortlepp, Angelika

03 April 2007

This research project investigates the viability of using renewable energy sources and passive solar design in Saskatchewan, with its harsh climate, abundant energy resources, and absence of financial incentives for residential renewable energy systems. <p>An experimental Ready-To-Move (RTM) house, using passive solar design and stand-alone solar and wind power with gas generator backup, was designed and built and has been tested for a one year period from January to December, 2006.<p>The design methodology was based on well established design procedures for passive solar homes and renewable energy systems that are documented in the literature. A data collection system was used to record solar and wind charging currents, and battery status and temperature data was recorded on a daily basis. Average household loads were estimated from this data. <p>For 2006, the power generation of the solar array was 990 kWh, which was better than the expected output of 927 kWh. However, the wind generator produced only 475 kWh, which was substantially less the expected output of 1430 kWh. Average wind speeds were lower than the normal for 2006 and power production was less than the manufacturers projections for the specified wind speeds. Financial analysis showed that the lack of incentives and net metering made an off-grid system economically feasible only in remote locations where the cost of grid connection is over $20,000.

energy efficient design

photovoltaic

Application of energy saving systems in Hong Kong buildings /

Chu, Yiu-cheong.

January 2002

Thesis (M. Sc.)--University of Hong Kong, 2002. / Includes bibliographical references.

Buildings Photovoltaic power generation.

Production of polycrystalline silicon thin films on foreign substrates using electron cyclotron resonance plasma enhanced chemical vapour deposition

Summers, Scott

January 2003

The wide spread adoption of solar photovoltaic cells is impeded by a number of factors, the primary one of which is the cost. The technology behind the most used cells today is based on bulk single crystalline silicon wafers. These wafers subsequently undergo numerous processesto produce a finished module capableo f delivering usable direct current electricity. Even with all these processes, the single biggest contributor to production costs is the starting wafer - estimated to account for some 50% of manufacturing costs. Removing these costs by replacing the wafer is the leading topic in solar cell research today. Glass is the most convenient starting point for replacing silicon wafers - it is benign, both from an environmental and manufacturing viewpoint, and is considerably less expensive than silicon wafers for a given quantity. As an amorphous material, glass is well suited to acting as a substrate for amorphous silicon layers used in low cost cells. Amorphous silicon cells suffer from stability issues and can degrade in performance substantially over the operational lifetime of the solar cell. To overcomethese problems the amorphous silicon can be replaced with crystalline silicon material. Generally, the deposition of suitable crystalline material occurs at a temperature in excess of the softening point of glass. So however useful glass is as a substrate it is incompatible with simple, low temperature formation of crystalline silicon using most techniques. There are two outstanding issues relating to the manufacture of thin film silicon solar cells that have been researched for this thesis. One is the deposition of silicon layers at a growth rate high enough to allow for a reasonable throughput of material. The second is the production of material suited to the task i.e. structurally and electrically. In this thesis the direct deposition of high quality polycrystalline silicon( near-single orientation with suitable electrical characteristics) using electron cyclotron resonance plasma enhanced chemical vapour deposition(E CR PECVD) onto glass is demonstrated. A new visualisation of the magnetic field used in E R PECVD has given an insight into the optimisation of the deposition process using this technique. By adjusting the magnetic field appropriately, an increase in growth rate for deposition of polycrystalline silicon of 2- 25 times that reported in the literature was found. In addition to the characterisation of the deposited material, the process parameters have been fully investigated by analysing the process plasma characteristics using a Langmuir probe. An amorphous incubation layer 1 micron thick is seen when the polycrystalline material is deposited directly on glass, however this layer can be substantially reduced by depositing on a thin layer of silicon (on the glass) which has been crystallised by excimer laser irradiation. This indicatesa possible direction in combining these two approaches in future manufacturing processes for the growth of low-temperature polycrystalline silicon layers on glass to form photovoltaic devices.

621.381542

Solar photovoltaic cells

Strategies for improving solution-processed ZnO/Cu₂O photovoltaics

Gershon, Talia

January 2012

No description available.

669

Photovoltaic power generation