Author: 吳俊杰Publisher:
ISBN:
Category :
Languages : en
Pages :
Book Description
Preparation and Characterization of Silver Copper Indium Gallium Diselenide Thin-film Solar Cells
Author: 吳俊杰Preparation and Characterization of Copper Indium Gallium Diselenide Powders and Films Used in the Absorber Layer of Thin-film Solar Cells
Author: 吳忠憲Preparation and Characterization of Copper Indium Gallium Diselenide Films Used in the Absorber Layers of Thin-film Solar Cells
Author: 陳富珊Synthesis and Characterization of Silver Copper Indium Gallium Diselenide Solar Cells on Flexible Substrates
Author: Preparation and Characterization of Copper Indium Gallium Diselenide and Copper Zinc Tin Sulfide Powders Used as the Absorber of Thin-film Solar Cells
Author: 林詣軒Preparation and Characterization of Silver Indium Diselenide Used as the Absorber in Thin-film Solar Cells
Author: 簡思佳Optical and Photovoltaic Properties of Copper Indium-gallium Diselenide Materials and Solar Cells
Author: Puruswottam AryalPublisher:
ISBN:
Category : Copper indium selenide
Languages : en
Pages : 365
Book Description
The demand for clean and renewable energy sources in recent years has motivated research on the development of low cost, thin film photovoltaic devices. As a consequence, tools for the investigation and characterization of thin film photovoltaic component materials and devices, which can be implemented in real time as well as under in-line and off-line measurement conditions, are becoming increasingly important. Real time spectroscopic ellipsometry (RTSE) and ex-situ mapping spectroscopic ellipsometry (SE) are powerful characterization tools suitable for applications in the optimization of device performance and the evaluation of thin film photovoltaics technology scale-up from dot cell sizes in research laboratories to full module sizes in factories. These non-destructive optical probes implement multichannel spectroscopic detection for achieving high measurement speed, while simultaneously yielding high precision light-matter interaction parameters. The interaction parameters can be analyzed to obtain layer thicknesses as well as their optical properties from which material properties such as composition can be determined. The layer thicknesses and their optical properties in turn provide insights into the fraction of incident light absorbed in the active layer of the solar cell and also provide a basis for short-circuit current optimization through optical simulations. In this dissertation research, Cu(In, Ga)Se2 films with different Ga contents have been prepared by a one stage co-evaporation process. These films have been studied by spectroscopic ellipsometry (RTSE) in real time during their deposition, which has been performed at high temperature (570oC). After cooling the films to room temperature, in-situ SE measurements were undertaken in order to extract the dielectric functions of the thin film materials. An extended parameterization was established through the fitting of these dielectric functions to analytical functions, followed by the development of expressions in the free parameters that describe these analytical functions versus the Ga content. As a result of this parameterization, dielectric function spectra can be predicted for any desired composition. This capability was applied for the structural and compositional mapping of CIGS thin films and solar cells deposited over 10 cm × 10 cm substrate areas. Correlations of the deduced structural and compositional parameters with the corresponding device performance characteristics have yielded important insights with the potential to assist in the optimization of solar cell devices incorporating thin CIGS layers. In addition, a methodology of external quantum efficiency simulation (EQE) has been developed that relies on ex-situ spectroscopic ellipsometry analysis of complete thin film solar cells and so does not require free parameters. The simulations have been applied to CIGS and a-Si:H solar cells, based on the assumption that all photo-generated carriers within the active layers of these cells are collected without any recombination losses. Thus, it should be noted the predicted EQE is the maximum that the solar cell having the given structure can generate, and the difference between the predicted and measured EQE for the same device can provide insights into recombination losses in the device. Because the predicted EQE is based on specular interfaces, it can also be lower than the measured values due to light trapping caused by rough surfaces and interfaces. In another research area of interest for CIGS materials and solar cells, the role of the stage II/III substrate temperature (540oC - 640oC) in the deposition of the films by the three stage process has been studied, as has its effect on device performance, sodium diffusion, and grain size. Since standard soda-lime glass does not tolerate temperatures above 570oC due to glass softening, specially engineered high temperature soda-lime glass produced by Nippon Electric Glass Co., Japan was used as the substrate material in this study. It was found that the average device performance improves up to 620oC as a consequence of reduced shunting and improved diode quality factor which affect the fill factor of the device. At 640oC, however, these parameters have exhibited a wider distribution, and thus have yielded a lower average efficiency for the cells. SEM micrographs of these devices showed that the grain size first increased with increasing temperature up to 620oC, and then showed a bimodal distribution at 640oC. Finally, ex-situ mapping ellipsometry has been applied in the study of silver nanoparticle thin films prepared by the drop casting method. These films are important because of the plasmonic effects they exhibit. Such effects can be exploited by integrating the nanoparticle layers into solar cells in order to promote light trapping, and hence, increase the overall efficiency of the cells. A study of these films with mapping spectroscopic ellipsometry provides a means of determining thickness uniformity over large areas that is critical for scale-up of the deposition processes. The uniformity of other parameters of the films such as the plasmon resonance energy and its broadening are equally important to ensure maximum coupling of light into the solar cell absorber layer.
Chemical and Electronic Characterization of Copper Indium Gallium Diselenide Thin Film Solar Cells and Correlation of These Characteristics to Solar Cell Operation
Author: Michael Justin HetzerPublisher:
ISBN:
Category : Copper indium selenide
Languages : en
Pages : 158
Book Description
Abstract: This dissertation embodies solid state physics research to understand the basic physical mechanisms underlying the movement of charge inside solar cells, in particular, the high efficiency copper indium gallium diselenide (CIGS) solar cell. The fundamental physics of the operation of these complex polycrystalline alloys remains incompletely understood. CIGS based solar cells have obtained conversion efficiencies of nearly 20%. Solar cells based on this material have been examined in this work using high resolution, atomic scale techniques to better understand the fundamental operation of these solar cells as well as correlating these basic properties to the operation of the finished full solar cell devices. Auger Electron Spectroscopy (AES) measurements of the chemical composition taken with nanometer resolution in an ultra high vacuum secondary electron microscope show evidence for compositional changes at the grain boundaries of the CIGS layer. These findings support theoretical calculations that predict higher solar cell performance as a result. Additionally, measurements have been taken with cathodoluminescence spectroscopy (CLS) studying the band structure locally within the CIGS layers. Significant variation is present in the resulting spectra, even within single grains indicating improved uniformity could be a path to better solar cell operation. Attempts to correlate the chemical composition and the energy band structure using AES and CLS measurements have yielded some interesting initial results but more work remains to be done to obtain a deeper understanding of the physics involved in these solar cells. Correlations have been observed between the energy band structure and the performance parameters of the solar cell, such as efficiency. These results indicate the possibility of alloying between the different layers of the solar cell and also that this intermixing is detrimental to the performance of the solar cell. This work has revealed important fundamental characteristics of these materials regarding changes in the atomic composition and energy band structure and how these changes influence the performance of the CIGS layer.
Advanced Characterization of Thin Film Solar Cells
Author: Mowafak Al-JassimPublisher: Institution of Engineering and Technology
ISBN: 1839530235
Category : Technology & Engineering
Languages : en
Pages : 457
Book Description
Polycrystalline thin-film solar cells have reached a levelized cost of energy that is competitive with all other sources of electricity. The technology has significantly improved in recent years, with laboratory cell efficiencies for cadmium telluride (CdTe), perovskites, and copper indium gallium diselenide (CIGS) each exceeding 22 percent. Both CdTe and CIGS solar panels are now produced at the gigawatt scale. However, there are ongoing challenges, including the continued need to improve performance and stability while reducing cost. Advancing polycrystalline solar cell technology demands an in-depth understanding of efficiency, scaling, and degradation mechanisms, which requires sophisticated characterization methods. These methods will enable researchers and manufacturers to improve future solar modules and systems.
Preparation and Characterization of Copper Indium Diselenide-based Solar Cells with a Thin Zinc Selenide Intermediate Layer
Author: Ji-Beom YooPublisher:
ISBN:
Category : Copper indium selenide
Languages : en
Pages : 300
Book Description