Electronic characterisation of earth-abundant sulphides for solar photovoltaics / Thomas James Whittles.
Whittles, Thomas James, author.
2018
TK8322
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Title Electronic characterisation of earth-abundant sulphides for solar photovoltaics / Thomas James Whittles.
Author Whittles, Thomas James, author.
ISBN 9783319916651 (electronic book)
3319916653 (electronic book)
3319916645
9783319916644
DOI https://doi.org/10.1007/978-3-319-91665-1
Publication Details Cham, Switzerland : Springer, 2018.
Language English
Description 1 online resource.
Item Number 10.1007/978-3-319-91665-1 doi
Call Number TK8322
Dewey Decimal Classification 621.31/244
Summary This book examines the electronic structure of earth-abundant and environmentally friendly materials for use as absorber layers within photovoltaic cells. The corroboration between high-quality photoemission measurements and density of states calculations yields valuable insights into why these materials have demonstrated poor device efficiencies in the vast literature cited. The book shows how the materials' underlying electronic structures affect their properties, and how the band positions make them unsuitable for use with established solar cell technologies. After explaining these poor efficiencies, the book offers alternative window layer materials to improve the use of these absorbers. The power of photoemission and interpretation of the data in terms of factors generally overlooked in the literature, such as the materials' oxidation and phase impurity, is demonstrated. Representing a unique reference guide, the book will be of considerable interest and value to members of the photoemission community engaged in solar cell research, and to a wider materials science audience as well.
Note Doctoral thesis accepted by the University of Liverpool, Liverpool, UK.
Bibliography, etc. Note Includes bibliographical references.
Access Note Access limited to authorized users.
Digital File Characteristics text file PDF
Source of Description Online resource; title from PDF title page (viewed August 8, 2018).
Series Springer theses.
Available in Other Form Print version: 9783319916644
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Intro; Supervisor's Foreword; Abstract; Publications and Presentations; Work Done in Conjunction with Others; Acknowledgements; Contents; Abbreviations; Symbols; 1 Introduction; 1.1 Energy; 1.1.1 The Problem; 1.1.2 The Solutions; 1.1.3 The Case for Solar Energy; 1.2 Solar Photovoltaics; 1.2.1 Semiconductor Theory; 1.2.2 Photovoltaic Devices; 1.3 A Brief History of Solar Cells; 1.3.1 0th Generation: The Early Years; 1.3.2 1st Generation: Wafer-Based PV; 1.3.3 2nd Generation: Commercial Thin-Film; 1.3.4 3rd Generation: Everything Else, Dependent upon Research Interests.

1.4 Earth-Abundant Thin-Film Solar Cells1.4.1 Why Sulphides?; 1.4.2 Cu-Based Earth-Abundant Post-transition Metal Sulphides; 1.5 Efficiency: The Quintessential Goal of Solar Cell Research?; 1.5.1 Standards; 1.5.2 Record Efficiencies; 1.5.3 A Few Words on Deployment; 1.6 Characterisation of Solar Cells; 1.6.1 Usual Techniques; 1.6.2 The Importance of Electronic Characterisation; 1.7 Overview of the Thesis; 1.7.1 Structure; 1.7.2 Aims; References; 2 Experimental Methods; 2.1 Material Growth Methods; 2.1.1 Single Crystal Growth Methods; 2.1.2 Thin-Film Growth Methods; 2.2 Ultrahigh Vacuum.

2.2.1 The Necessity for Vacuum2.2.2 Achieving UHV; 2.2.3 A 3-Chamber Surface Science System; 2.2.4 A Single-Chamber Electronic Characterisation System; 2.3 Photoemission Spectroscopy; 2.3.1 Principles and Theory; 2.3.2 Operation and Implementation; 2.3.3 Spectrometer Calibrations; 2.3.4 Spectral Analysis; 2.4 Density Functional Theory; 2.4.1 Introduction; 2.4.2 Implementation; 2.5 Fourier Transform Infrared Spectroscopy; 2.5.1 Principles and Theory; 2.5.2 Operation and Implementation; 2.6 X-Ray Diffraction; 2.6.1 Principles and Theory; 2.6.2 Operation and Implementation.

2.7 Raman Spectroscopy2.7.1 Principles and Theory; 2.7.2 Operation and Implementation; 2.8 Energy-Dispersive X-Ray Spectroscopy; 2.9 Summary; References; 3 The Electronic Structure of CuSbS2 for Use as a PV Absorber; 3.1 CuSbS2: The Material; 3.1.1 History; 3.1.2 CuSbS2 as a Solar Absorber; 3.1.3 Structure; 3.1.4 Motivation and Scope of This Study; 3.2 Experimental Details; 3.2.1 Growth of CuSbS2 Films; 3.2.2 Characterisation of CuSbS2 Films; 3.3 Electronic Structure Studies of High-Quality CuSbS2 Films; 3.3.1 Phase-Purity; 3.3.2 XPS Core-Level Analysis; 3.3.3 Natural Band Alignments.

3.3.4 Density of States Analysis3.4 Further Effects of Contamination and the Thermal Treatment of CuSbS2; 3.4.1 The Effects of Contamination; 3.4.2 The Effects of the Thermal Treatment; 3.5 Summary; References; 4 The Electronic Structure of Cu3BiS3 for Use as a PV Absorber; 4.1 Cu3BiS3: The Material; 4.1.1 History and Uses; 4.1.2 Cu3BiS3 as a Solar Absorber; 4.1.3 Structure; 4.1.4 Motivation and Scope of This Study; 4.2 Experimental Details; 4.2.1 Growth of Cu3BiS3 Films; 4.2.2 Characterisation of Cu3BiS3; 4.3 Electronic Structure Studies of Cu3BiS3; 4.3.1 Phase-Purity.

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