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Submit a ProposalFundamentals of Solar Cell Design
 | Edited by Inamuddin, Mohd Imran Ahamed, Rajender Boddula, and Mashallah Rezakazemi
Copyright: 2021 | Status: Published ISBN: 9781119724704 | Hardcover | 561 pages Price: $225 USD  |
One Line Description
Edited by one of the most well-respected and prolific engineers in the world and his team, this book provides a comprehensive overview of solar cells and explores the history of evolution and present scenarios of solar cell design, classification, properties, various semiconductor materials, thin films, wafer-scale, transparent solar cells, and other fundamentals of solar cell design.
Audience
This book is a unique reference guide that can be used by faculty, students, researchers, engineers, device designers and industrialists who are working and learning in the fields of semiconductors, chemistry, physics, electronics, light science, material science, flexible energy conversion, industrial, and renewable energy sectors.
This book is a unique reference guide that can be used by faculty, students, researchers, engineers, device designers and industrialists who are working and learning in the fields of semiconductors, chemistry, physics, electronics, light science, material science, flexible energy conversion, industrial, and renewable energy sectors.
Description
Solar cells are semiconductor devices that convert light photons into electricity in photovoltaic energy conversion and can help to overcome the global energy crisis. Solar cells have many applications including remote area power systems, earth-orbiting satellites, wristwatches, water pumping, photodetectors and remote radiotelephones. Solar cell technology is economically feasible for commercial-scale power generation. While commercial solar cells exhibit good performance and stability, still researchers are looking at many ways to improve the performance and cost of solar cells via modulating the fundamental properties of semiconductors. Solar cell technology is the key to a clean energy future. Solar cells directly harvest energy from the sun’s light radiation into electricity are in an ever-growing demand for future global energy production.
Solar cell-based energy harvesting has attracted worldwide attention for their notable features, such as cheap renewable technology, scalable, lightweight, flexibility, versatility, no greenhouse gas emission, environment, and economy friendly and operational costs are quite low compared to other forms of power generation. Thus, solar cell technology is at the forefront of renewable energy technologies which are used in telecommunications, power plants, small devices to satellites. Aiming at large-scale implementation can be manipulated by various types used in solar cell design and exploration of new materials towards improving performance and reducing cost. Therefore, in-depth knowledge about solar cell design is fundamental for those who wish to apply this knowledge and understanding in industries and academics.
This book provides a comprehensive overview on solar cells and explores the history to evolution and present scenarios of solar cell design, classification, properties, various semiconductor materials, thin films, wafer-scale, transparent solar cells, and so on. It also includes solar cells’ characterization analytical tools, theoretical modeling, practices to enhance conversion efficiencies, applications and patents.
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Solar cells are semiconductor devices that convert light photons into electricity in photovoltaic energy conversion and can help to overcome the global energy crisis. Solar cells have many applications including remote area power systems, earth-orbiting satellites, wristwatches, water pumping, photodetectors and remote radiotelephones. Solar cell technology is economically feasible for commercial-scale power generation. While commercial solar cells exhibit good performance and stability, still researchers are looking at many ways to improve the performance and cost of solar cells via modulating the fundamental properties of semiconductors. Solar cell technology is the key to a clean energy future. Solar cells directly harvest energy from the sun’s light radiation into electricity are in an ever-growing demand for future global energy production.
Solar cell-based energy harvesting has attracted worldwide attention for their notable features, such as cheap renewable technology, scalable, lightweight, flexibility, versatility, no greenhouse gas emission, environment, and economy friendly and operational costs are quite low compared to other forms of power generation. Thus, solar cell technology is at the forefront of renewable energy technologies which are used in telecommunications, power plants, small devices to satellites. Aiming at large-scale implementation can be manipulated by various types used in solar cell design and exploration of new materials towards improving performance and reducing cost. Therefore, in-depth knowledge about solar cell design is fundamental for those who wish to apply this knowledge and understanding in industries and academics.
This book provides a comprehensive overview on solar cells and explores the history to evolution and present scenarios of solar cell design, classification, properties, various semiconductor materials, thin films, wafer-scale, transparent solar cells, and so on. It also includes solar cells’ characterization analytical tools, theoretical modeling, practices to enhance conversion efficiencies, applications and patents.
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Supplementary Data
--Provides state-of-the-art information about solar cells
--Is a unique reference guide for researchers in solar energy
--Includes novel innovations in the field of solar cell technology
--Provides state-of-the-art information about solar cells
--Is a unique reference guide for researchers in solar energy
--Includes novel innovations in the field of solar cell technology
Author / Editor Details
Inamuddin, PhD, is an assistant professor at the Department of Applied Chemistry, Zakir Husain College of Engineering and Technology, Faculty of Engineering and Technology, Aligarh Muslim University, Aligarh, India. He has extensive research experience in analytical chemistry, materials chemistry, electrochemistry, renewable energy, and environmental science. He has worked on different research projects funded by various government agencies and universities and is the recipient of multiple awards, including the Fast Track Young Scientist Award and the Young Researcher of the Year Award for 2020, from Aligarh Muslim University. He has published almost 200 research articles in various international scientific journals, 18 book chapters, and 120 edited books with multiple well-known publishers.
Inamuddin, PhD, is an assistant professor at the Department of Applied Chemistry, Zakir Husain College of Engineering and Technology, Faculty of Engineering and Technology, Aligarh Muslim University, Aligarh, India. He has extensive research experience in analytical chemistry, materials chemistry, electrochemistry, renewable energy, and environmental science. He has worked on different research projects funded by various government agencies and universities and is the recipient of multiple awards, including the Fast Track Young Scientist Award and the Young Researcher of the Year Award for 2020, from Aligarh Muslim University. He has published almost 200 research articles in various international scientific journals, 18 book chapters, and 120 edited books with multiple well-known publishers.
Mohd Imran Ahamed, PhD, is a research associate in the Department of Chemistry, Aligarh Muslim University, Aligarh, India. He has published several research and review articles in various international scientific journals and has co-edited multiple books. His research work includes ion-exchange chromatography, wastewater treatment, and analysis, bending actuator and electrospinning.
Rajender Boddula, PhD, is currently working for the Chinese Academy of Sciences President’s International Fellowship Initiative (CAS-PIFI) at the National Center for Nanoscience and Technology (NCNST, Beijing). His academic honors include multiple fellowships and scholarships, and he has published many scientific articles in international peer-reviewed journals. He is also serving as an editorial board member and a referee for several reputed international peer-reviewed journals. He has published edited books with numerous publishers and has authored over twenty book chapters.
Mashallah Rezakazemi, PhD, received his doctorate from the University of Tehran (UT) in 2015. In his first appointment, he served as associate professor in the Faculty of Chemical and Materials Engineering at Shahrood University of Technology. He has co-authored in more than 140 highly cited journal publications, conference articles and book chapters. He has received numerous major awards and grants from various funding agencies in recognition of his research. Notable among these are Khwarizmi Youth Award from the Iranian Research Organization for Science and Technology (IROST), and the Outstanding Young Researcher Award in Chemical Engineering from the Academy of Sciences of Iran. He was named a top 1% most Highly Cited Researcher by Web of Science (ESI).
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Table of Contents
Preface xv
1 Organic Solar Cells 1
Yadavalli Venkata Durga Nageswar
and Vaidya Jayathirtha Rao
1.1 Introduction 2
1.2 Classification of Solar Cells 3
1.3 Solar Cell Structure 4
1.4 Photovoltaic Parameters or Terminology Used in BHJOSCs 5
1.4.1 Open Circuit Voltage Voc 5
1.4.2 Short-Circuit Current Jsc 5
1.4.3 Incident-Photon-to-Current Efficiency (IPCE) 5
1.4.4 Power Conversion Efficiency ηp (PCE) 6
1.4.5 Fill Factor (FF) 6
1.5 Some Basic Design Principles/Thumb Rules Associated
With Organic Materials Required for BHJOSCs 6
1.6 Recent Research Advances in Small-Molecule Acceptor
and Polymer Donor Types 7
1.7 Recent Research Advances in All Small-Molecule
Acceptor and Donor Types 30
1.8 Conclusion 47
Acknowledgement 48
References 48
2 Plasmonic Solar Cells 55
T. Shiyani, S. K. Mahapatra and I. Banerjee
2.1 Introduction 56
2.1.1 Plasmonic Nanostructure 58
2.1.2 Classification of Plasmonic Nanostructures 59
2.2 Principles and Working Mechanism of Plasmonic
Solar Cells 60
2.2.1 Working Principle 60
2.2.2 Mechanism of Plasmonic Solar Cells 61
2.3 Important Optical Properties 62
2.3.1 Trapping of Light 63
2.3.2 Scattering and Absorption of Sunlight 63
2.3.3 Multiple Energy Levels 63
2.4 Advancements in Plasmonic Solar Cells 64
2.4.1 Direct Plasmonic Solar Cells 65
2.4.2 Plasmonic-Enhanced Solar Cell 69
2.4.3 Plasmonic Thin Film Solar Cells 69
2.4.4 Plasmonic Dye Sensitized Solar Cells (PDSSCs) 70
2.4.5 Plasmonic Photoelectrochemical Cells 71
2.4.6 Plasmonic Quantum Dot (QD) Solar Cells 71
2.4.7 Plasmonic Perovskite Solar Cells 72
2.4.8 Plasmonic Hybrid Solar Cells 72
2.5 Conclusion and Future Aspects 72
Acknowledgements 73
References 73
3 Tandem Solar Cell 83
Umesh Fegade
List of Abbreviations 83
3.1 Introduction 85
3.2 Review of Organic Tandem Solar Cell 86
3.3 Review of Inorganic Tandem Solar Cell 89
3.4 Conclusion 95
References 96
4 Thin-Film Solar Cells 103
Gobinath Velu Kaliyannan, Raja Gunasekaran,
Santhosh Sivaraj, Saravanakumar Jaganathan
and Rajasekar Rathanasamy
4.1 Introduction 104
4.2 Why Thin-Film Solar Cells? 105
4.3 Amorphous Silicon 105
4.4 Cadmium Telluride 108
4.5 Copper Indium Diselenide Solar Cells 111
4.6 Comparison Between Flexible a-Si:H, CdTe,
and CIGS Cells and Applications 112
4.7 Conclusion 113
References 114
5 Biohybrid Solar Cells 117
Sapana Jadoun and Ufana Riaz
Abbreviation 117
5.1 Introduction 118
5.2 Photovoltaics 119
5.3 Solar Cells 119
5.3.1 First Generation 120
5.3.2 Second Generation 120
5.3.3 Third Generation 120
5.3.4 Fourth Generation 121
5.4 Bio-Hybrid Solar Cells 121
5.5 Role of Photosynthesis 122
5.6 Plant-Based Biohybrid Devices 122
5.6.1 PS I–Based Biohybrid Devices 123
5.6.2 PS II–Based Biohybrid Devices 125
5.7 Dye-Sensitized Solar Cells 126
5.8 Polymer and Semiconductors-Based Biohybrid Solar Cells 126
5.9 Conclusion 129
References 129
6 Dye-Sensitized Solar Cells 137
Santhosh Sivaraj, Gobinath Velu Kaliyannan,
Mohankumar Anandraj, Moganapriya Chinnasamy
and Rajasekar Rathanasamy
6.1 Introduction 138
6.2 Cell Architecture and Working Mechanism 139
6.3 Fabrication of Simple DSSC in Lab Scale 142
6.4 Electrodes 144
6.5 Counter Electrode 145
6.6 Blocking Layer 146
6.7 Electrolytes Used 147
6.7.1 Liquid-Based Electrolytes 148
6.7.1.1 Electrical Additives 148
6.7.1.2 Organic Solvents 148
6.7.1.3 Ionic Liquids 149
6.7.1.4 Iodide/Triiodide-Free Mediator
and Redox Couples 149
6.7.2 Quasi-Solid State Electrolytes 149
6.7.2.1 Thermoplastic-Based Polymer Electrolytes 150
6.7.2.2 Thermosetting Polymer Electrolytes 150
6.7.3 Solid-State Transport Materials 150
6.7.3.1 Inorganic Hole Transport Materials 151
6.7.3.2 Organic Hole Transport Materials 151
6.7.3.3 Solid-State Ionic Conductors 151
6.8 Commonly Used Natural Dyes in DSSC 152
6.8.1 Chlorophyll 152
6.8.2 Flavonoids 152
6.8.3 Anthocyanins 153
6.8.4 Carotenoids 154
6.9 Calculations 154
6.9.1 Power Conversion Efficiency 154
6.9.2 Fill Factor 163
6.9.3 Open-Circuit Voltage 163
6.9.4 Short Circuit Current 163
6.9.5 Determination of Energy Gap of Electrode
Material Adsorbed With Natural Dye 163
6.9.6 Absorption Coefficient 164
6.9.7 Dye Adsorption 164
6.10 Conclusion 164
References 165
7 Characterization and Theoretical Modeling of Solar Cells 169
Masoud Darvish Ganji, Mahyar Rezvani
and Sepideh Tanreh
7.1 Introduction 170
7.2 Classification of SC 172
7.2.1 Inorganic Solar Cells 173
7.2.2 Organic Solar Cell 173
7.3 Working Principle of DSSC 175
7.4 Operation Principle of DSSC 176
7.5 Photovoltaic Parameters 177
7.6 Theoretical and Computational Methods 181
7.6.1 Density Functional Theory (DFT) 182
7.6.2 Basis Sets 183
7.6.3 TDDFT Method 183
7.6.4 Molecular Descriptors 184
7.6.5 Force Field Parameterization for MD Simulations 188
7.6.6 Excited States 189
7.6.7 UV-Vis Spectroscopy 190
7.6.8 Charge Transfer and Carrier Transport 192
7.6.9 Coarse-Grained (CG) Simulations 193
7.6.10 Kinetic Monte Carlo (KMC) Modeling 193
7.6.11 Car-Parrinello Method 195
7.6.12 Solvent Effects 196
7.6.13 Global Reactivity Descriptors 196
7.7 Conclusion 198
References 199
8 Efficient Performance Parameters for Solar Cells 217
Figen Balo and Lutfu S.Sua
8.1 Introduction 218
8.1.1 Potential, Production, and Climate of Ankara 225
8.2 Solar Radiation Intensity Calculation 225
8.2.1 Horizontal Superficies 225
8.2.1.1 On a Daily Basis Total Sun Irradiation 225
8.2.1.2 Daily Diffuse Sun Irradiation 227
8.2.1.3 Momentary Total Sun Irradiation 227
8.2.1.4 Direct and Diffuse Sun Radiation 228
8.2.2 On Inclined Superficies, Computing
Sun Irradiation Intensity 228
8.2.2.1 Direct Momentary Sun Radiation 228
8.2.2.2 Diffuse Sun Radiation 228
8.2.2.3 Momentary Reflecting Radiation 229
8.2.2.4 Total Sun Radiation 229
8.3 Methodology 229
8.3.1 The Solar Radiation Assessments by Correlation
Models With MATLAB Simulation Software 229
8.3.2 MATLAB Simulation Results and Findings 233
8.3.3 For Ankara Province, the Determine of the Most
Efficiency Solar Cell With AHP Methodology 233
8.4 Conclusions 238
References 240
9 Practices to Enhance Conversion Efficiencies in Solar Cell 247
Andreea Irina Barzic
9.1 Introduction 247
9.2 Basics on Conversion Efficiency 249
9.3 Approaches for Improving Conversion Efficiencies
in Solar Cells 253
9.4 General Concluding Remarks 264
Acknowledgements 264
References 265
10 Solar Cell Efficiency Energy Materials 271
Zeeshan Abid, Faiza Wahad, Sughra Gulzar,
Muhammad Faheem Ashiq, Muhammad Shahid Aslam,
Munazza Shahid, Muhammad Altaf
and Raja Shahid Ashraf
10.1 Introduction 272
10.2 Solar Cell Efficiency 274
10.3 Historical Development of Solar Cell Materials 275
10.4 Solar Cell Materials and Efficiencies 277
10.4.1 Crystalline Silicon 278
10.4.2 Silicon Thin-Film Alloys 282
10.4.3 III-V Semiconductors 284
10.4.4 Chalcogenide 286
10.4.4.1 Chalcopyrites 286
10.4.4.2 Cadmium Telluride (CdTe) 288
10.4.5 Organic Materials 289
10.4.6 Hybrid Organic-Inorganic Materials 293
10.4.6.1 Dye-Sensitized Solar Cell Materials 293
10.4.6.2 Perovskites 296
10.4.7 Quantum Dots 300
10.5 Conclusion and Prospects 302
References 303
11 Analytical Tools for Solar Cell 317
Mohamad Saufi Rosmi, Ong Suu Wan,
Mohamad Azuwa Mohamed, Zul Adlan Mohd Hir
and Wan Nur Aini Wan Mokhtar
11.1 Introduction 318
11.2 Transient Absorption Spectroscopy 319
11.2.1 Application of Transient Absorption
Spectroscopy in Solar Cells 320
11.3 Electron Tomography 323
11.3.1 Application of Electron Tomography
(ET) in Solar Cells 324
11.4 Conductive Atomic Force Microscopy (C-AFM) 327
11.4.1 Application of C-AFM in Solar Cells 329
11.5 Kelvin Probe Force Microscopy 330
11.5.1 Application of Scanning Kelvin Probe Force
Microscopy for Solar Cells 334
11.6 Field Emission Scanning Electron Microscopy
and Transmission Electron Microscopy 335
11.6.1 Application of Field Emission Scanning
Electron Microscopy and Transmission
Electron Microscopy in Solar Cell 338
11.7 Conclusion 340
References 340
12 Applications of Solar Cells 345
Mohd Imran Ahamed and Naushad Anwar
12.1 Introduction 345
12.2 An Overview on Photovoltaic Cell 348
12.2.1 History 348
12.2.2 Working Principle of Solar Cell 348
12.2.3 First-Generation Photovoltaic Cells:
Crystalline Silicon Form 351
12.2.4 Second-Generation Photovoltaic Cells:
Thin Film Solar Cells 352
12.2.5 Third-Generation Photovoltaic Cells 353
12.3 Applications of Solar Cells 354
12.3.1 Perovskite Solar Cell 354
12.3.2 Dye-Sensitized Solar Cell 355
12.3.3 Nanostructured Inorganic-Organic
Heterojunction Solar Cells (NSIOHSCs) 356
12.3.4 Polymer Solar Cells 357
12.3.5 Quantum Dot Solar Cell (QDCs) 358
12.3.6 Organic Solar Cells 360
12.4 Outlook and Summary 362
References 362
13 Challenges of Stability in Perovskite Solar Cells 371
Mutayyab Afreen, Jazib Ali and Muhammad Bilal
13.1 Introduction 371
13.2 Degradation Phenomena and Stability Measures
in Perovskite 373
13.2.1 Thermal Stability 373
13.2.2 Structural and Chemical Stability 375
13.2.3 Oxygen and Moisture 376
13.2.4 Visible and UV Light Exposure 378
13.3 Stability-Interface Interplay 379
13.3.1 Chemical Reaction at the Interface 379
13.3.2 Degradation on the Top Electrode 380
13.3.3 Hysteresis Phenomenon in PSC Devices 381
13.4 Effect of Selective Contacts on Stability 382
13.4.1 Electron-Transport Layers 382
13.4.2 Hole Transport Layers 384
13.4 Conclusion 387
References 387
14 State of the Art and Prospective of Solar Cells 393
Zahra Pezeshki and Abdelhalim Zekry
Acronyms 393
14.1 Introduction 396
14.2 State of the-Art of Solar Cells 396
14.2.1 Production Volume 400
14.2.2 Cost Breakdown 400
14.2.3 Main Technologies 401
14.2.3.1 Si Solar Cell Arrays 401
14.2.3.2 DSSCs 403
14.2.3.3 Photoanodes 404
14.2.3.4 C/Si Heterojunctions 405
14.2.3.5 a-C/Si Heterojunctions 407
14.2.3.6 Non-Fullerene Acceptor Bulk
Heterojunctions 407
14.2.3.7 a-Si 411
14.2.3.8 Perovskites 412
14.2.3.9 Metal-Halide–Based perovskites 413
14.2.3.10 Sn-Based Perovskites 416
14.2.3.11 Heavily Doped Solar Cells 421
14.2.3.12 PV Building Substrates 422
14.2.3.13 Solar Tracking System 423
14.2.3.14 Solar Concentrators 426
14.2.3.15 Solar Power Satellite 426
14.2.3.16 Roof-Top Solar PV System 428
14.2.3.17 Short-Wavelength Solar-Blind
Detectors 429
14.2.3.18 GCPVS 431
14.2.3.19 Microwave Heating in Si Solar
Cell Fabrication 432
14.2.3.20 Refrigeration PV System 434
14.2.3.21 Solar Collectors and Receivers 435
14.2.3.22 Solar Drying System 436
14.2.3.23 Water Networks With Solar PV Energy 437
14.2.3.24 Wind and Solar Integrated
to Smart Grid 438
14.2.3.25 Green Data Centers 442
14.3 Prospective of Solar Cells 445
14.4 Conclusion 447
References 448
15 Semitransparent Perovskite Solar Cells 461
Faiza Wahad, Zeeshan Abid, Sughra Gulzar,
Muhammad Shahid Aslam, Saqib Rafique,
Munazza Shahid, Muhammad Altaf
and Raja Shahid Ashraf
15.1 Introduction 462
15.2 Device Architectures 464
15.2.1 Conventional n-i-p Device Structure 465
15.2.2 Inverted p-i-n Device Structure 465
15.3 Optical Assessment 466
15.3.1 Average Visible Transmittance 466
15.3.2 Corresponding Color Temperature 467
15.3.3 Color Rendering Index 468
15.3.4 Transparency Color Perception 468
15.3.5 Light Management 471
15.4 Materials 474
15.4.1 Photoactive Layer 474
15.4.2 Charge Transport Layers (ETL and HTL) 479
15.4.3 Transparent Electrode 481
15.5 Applications 484
15.5.1 Building-Integrated Photovoltaics 484
15.5.2 Tandem Devices 486
15.6 Conclusion 492
References 492
16 Flexible Solar Cells 505
Santosh Patil, Rushi Jani, Nisarg Purabiarao, Archan Desai,
Ishan Desai and Kshitij Bhargava
16.1 Introduction 505
16.1.1 Need for Solar Energy Harnessing 505
16.1.2 Brief Overview of Generations of Solar Cells 506
16.1.3 Limitations of Solar Cells 508
16.1.4 What is Flexible Solar Cell (FSC)? 509
16.2 Materials for FSCs 510
16.2.1 Semiconductors 510
16.2.2 Substrates 512
16.2.3 Electrodes 513
16.2.4 Encapsulations 514
16.3 Thin-Film Deposition and Characterization 514
16.3.1 R2R Processing 515
16.3.2 Chemical Bath Deposition 516
16.3.3 Chemical Vapor Deposition 517
16.3.4 Dip Coating 518
16.3.5 Spin Coating 520
16.3.6 Screen Printing 521
16.4 Characterizations for FSCs 522
16.4.1 Material Characterization 523
16.4.2 Device Characterization 529
16.5 Issues in FSCs 531
16.6 Performance Comparison of RSCs and FSCs 532
16.7 Applications of Flexible Solar Cell 532
16.8 Conclusion 533
References 534
Index 537
Back to Top
Preface xv
1 Organic Solar Cells 1
Yadavalli Venkata Durga Nageswar
and Vaidya Jayathirtha Rao
1.1 Introduction 2
1.2 Classification of Solar Cells 3
1.3 Solar Cell Structure 4
1.4 Photovoltaic Parameters or Terminology Used in BHJOSCs 5
1.4.1 Open Circuit Voltage Voc 5
1.4.2 Short-Circuit Current Jsc 5
1.4.3 Incident-Photon-to-Current Efficiency (IPCE) 5
1.4.4 Power Conversion Efficiency ηp (PCE) 6
1.4.5 Fill Factor (FF) 6
1.5 Some Basic Design Principles/Thumb Rules Associated
With Organic Materials Required for BHJOSCs 6
1.6 Recent Research Advances in Small-Molecule Acceptor
and Polymer Donor Types 7
1.7 Recent Research Advances in All Small-Molecule
Acceptor and Donor Types 30
1.8 Conclusion 47
Acknowledgement 48
References 48
2 Plasmonic Solar Cells 55
T. Shiyani, S. K. Mahapatra and I. Banerjee
2.1 Introduction 56
2.1.1 Plasmonic Nanostructure 58
2.1.2 Classification of Plasmonic Nanostructures 59
2.2 Principles and Working Mechanism of Plasmonic
Solar Cells 60
2.2.1 Working Principle 60
2.2.2 Mechanism of Plasmonic Solar Cells 61
2.3 Important Optical Properties 62
2.3.1 Trapping of Light 63
2.3.2 Scattering and Absorption of Sunlight 63
2.3.3 Multiple Energy Levels 63
2.4 Advancements in Plasmonic Solar Cells 64
2.4.1 Direct Plasmonic Solar Cells 65
2.4.2 Plasmonic-Enhanced Solar Cell 69
2.4.3 Plasmonic Thin Film Solar Cells 69
2.4.4 Plasmonic Dye Sensitized Solar Cells (PDSSCs) 70
2.4.5 Plasmonic Photoelectrochemical Cells 71
2.4.6 Plasmonic Quantum Dot (QD) Solar Cells 71
2.4.7 Plasmonic Perovskite Solar Cells 72
2.4.8 Plasmonic Hybrid Solar Cells 72
2.5 Conclusion and Future Aspects 72
Acknowledgements 73
References 73
3 Tandem Solar Cell 83
Umesh Fegade
List of Abbreviations 83
3.1 Introduction 85
3.2 Review of Organic Tandem Solar Cell 86
3.3 Review of Inorganic Tandem Solar Cell 89
3.4 Conclusion 95
References 96
4 Thin-Film Solar Cells 103
Gobinath Velu Kaliyannan, Raja Gunasekaran,
Santhosh Sivaraj, Saravanakumar Jaganathan
and Rajasekar Rathanasamy
4.1 Introduction 104
4.2 Why Thin-Film Solar Cells? 105
4.3 Amorphous Silicon 105
4.4 Cadmium Telluride 108
4.5 Copper Indium Diselenide Solar Cells 111
4.6 Comparison Between Flexible a-Si:H, CdTe,
and CIGS Cells and Applications 112
4.7 Conclusion 113
References 114
5 Biohybrid Solar Cells 117
Sapana Jadoun and Ufana Riaz
Abbreviation 117
5.1 Introduction 118
5.2 Photovoltaics 119
5.3 Solar Cells 119
5.3.1 First Generation 120
5.3.2 Second Generation 120
5.3.3 Third Generation 120
5.3.4 Fourth Generation 121
5.4 Bio-Hybrid Solar Cells 121
5.5 Role of Photosynthesis 122
5.6 Plant-Based Biohybrid Devices 122
5.6.1 PS I–Based Biohybrid Devices 123
5.6.2 PS II–Based Biohybrid Devices 125
5.7 Dye-Sensitized Solar Cells 126
5.8 Polymer and Semiconductors-Based Biohybrid Solar Cells 126
5.9 Conclusion 129
References 129
6 Dye-Sensitized Solar Cells 137
Santhosh Sivaraj, Gobinath Velu Kaliyannan,
Mohankumar Anandraj, Moganapriya Chinnasamy
and Rajasekar Rathanasamy
6.1 Introduction 138
6.2 Cell Architecture and Working Mechanism 139
6.3 Fabrication of Simple DSSC in Lab Scale 142
6.4 Electrodes 144
6.5 Counter Electrode 145
6.6 Blocking Layer 146
6.7 Electrolytes Used 147
6.7.1 Liquid-Based Electrolytes 148
6.7.1.1 Electrical Additives 148
6.7.1.2 Organic Solvents 148
6.7.1.3 Ionic Liquids 149
6.7.1.4 Iodide/Triiodide-Free Mediator
and Redox Couples 149
6.7.2 Quasi-Solid State Electrolytes 149
6.7.2.1 Thermoplastic-Based Polymer Electrolytes 150
6.7.2.2 Thermosetting Polymer Electrolytes 150
6.7.3 Solid-State Transport Materials 150
6.7.3.1 Inorganic Hole Transport Materials 151
6.7.3.2 Organic Hole Transport Materials 151
6.7.3.3 Solid-State Ionic Conductors 151
6.8 Commonly Used Natural Dyes in DSSC 152
6.8.1 Chlorophyll 152
6.8.2 Flavonoids 152
6.8.3 Anthocyanins 153
6.8.4 Carotenoids 154
6.9 Calculations 154
6.9.1 Power Conversion Efficiency 154
6.9.2 Fill Factor 163
6.9.3 Open-Circuit Voltage 163
6.9.4 Short Circuit Current 163
6.9.5 Determination of Energy Gap of Electrode
Material Adsorbed With Natural Dye 163
6.9.6 Absorption Coefficient 164
6.9.7 Dye Adsorption 164
6.10 Conclusion 164
References 165
7 Characterization and Theoretical Modeling of Solar Cells 169
Masoud Darvish Ganji, Mahyar Rezvani
and Sepideh Tanreh
7.1 Introduction 170
7.2 Classification of SC 172
7.2.1 Inorganic Solar Cells 173
7.2.2 Organic Solar Cell 173
7.3 Working Principle of DSSC 175
7.4 Operation Principle of DSSC 176
7.5 Photovoltaic Parameters 177
7.6 Theoretical and Computational Methods 181
7.6.1 Density Functional Theory (DFT) 182
7.6.2 Basis Sets 183
7.6.3 TDDFT Method 183
7.6.4 Molecular Descriptors 184
7.6.5 Force Field Parameterization for MD Simulations 188
7.6.6 Excited States 189
7.6.7 UV-Vis Spectroscopy 190
7.6.8 Charge Transfer and Carrier Transport 192
7.6.9 Coarse-Grained (CG) Simulations 193
7.6.10 Kinetic Monte Carlo (KMC) Modeling 193
7.6.11 Car-Parrinello Method 195
7.6.12 Solvent Effects 196
7.6.13 Global Reactivity Descriptors 196
7.7 Conclusion 198
References 199
8 Efficient Performance Parameters for Solar Cells 217
Figen Balo and Lutfu S.Sua
8.1 Introduction 218
8.1.1 Potential, Production, and Climate of Ankara 225
8.2 Solar Radiation Intensity Calculation 225
8.2.1 Horizontal Superficies 225
8.2.1.1 On a Daily Basis Total Sun Irradiation 225
8.2.1.2 Daily Diffuse Sun Irradiation 227
8.2.1.3 Momentary Total Sun Irradiation 227
8.2.1.4 Direct and Diffuse Sun Radiation 228
8.2.2 On Inclined Superficies, Computing
Sun Irradiation Intensity 228
8.2.2.1 Direct Momentary Sun Radiation 228
8.2.2.2 Diffuse Sun Radiation 228
8.2.2.3 Momentary Reflecting Radiation 229
8.2.2.4 Total Sun Radiation 229
8.3 Methodology 229
8.3.1 The Solar Radiation Assessments by Correlation
Models With MATLAB Simulation Software 229
8.3.2 MATLAB Simulation Results and Findings 233
8.3.3 For Ankara Province, the Determine of the Most
Efficiency Solar Cell With AHP Methodology 233
8.4 Conclusions 238
References 240
9 Practices to Enhance Conversion Efficiencies in Solar Cell 247
Andreea Irina Barzic
9.1 Introduction 247
9.2 Basics on Conversion Efficiency 249
9.3 Approaches for Improving Conversion Efficiencies
in Solar Cells 253
9.4 General Concluding Remarks 264
Acknowledgements 264
References 265
10 Solar Cell Efficiency Energy Materials 271
Zeeshan Abid, Faiza Wahad, Sughra Gulzar,
Muhammad Faheem Ashiq, Muhammad Shahid Aslam,
Munazza Shahid, Muhammad Altaf
and Raja Shahid Ashraf
10.1 Introduction 272
10.2 Solar Cell Efficiency 274
10.3 Historical Development of Solar Cell Materials 275
10.4 Solar Cell Materials and Efficiencies 277
10.4.1 Crystalline Silicon 278
10.4.2 Silicon Thin-Film Alloys 282
10.4.3 III-V Semiconductors 284
10.4.4 Chalcogenide 286
10.4.4.1 Chalcopyrites 286
10.4.4.2 Cadmium Telluride (CdTe) 288
10.4.5 Organic Materials 289
10.4.6 Hybrid Organic-Inorganic Materials 293
10.4.6.1 Dye-Sensitized Solar Cell Materials 293
10.4.6.2 Perovskites 296
10.4.7 Quantum Dots 300
10.5 Conclusion and Prospects 302
References 303
11 Analytical Tools for Solar Cell 317
Mohamad Saufi Rosmi, Ong Suu Wan,
Mohamad Azuwa Mohamed, Zul Adlan Mohd Hir
and Wan Nur Aini Wan Mokhtar
11.1 Introduction 318
11.2 Transient Absorption Spectroscopy 319
11.2.1 Application of Transient Absorption
Spectroscopy in Solar Cells 320
11.3 Electron Tomography 323
11.3.1 Application of Electron Tomography
(ET) in Solar Cells 324
11.4 Conductive Atomic Force Microscopy (C-AFM) 327
11.4.1 Application of C-AFM in Solar Cells 329
11.5 Kelvin Probe Force Microscopy 330
11.5.1 Application of Scanning Kelvin Probe Force
Microscopy for Solar Cells 334
11.6 Field Emission Scanning Electron Microscopy
and Transmission Electron Microscopy 335
11.6.1 Application of Field Emission Scanning
Electron Microscopy and Transmission
Electron Microscopy in Solar Cell 338
11.7 Conclusion 340
References 340
12 Applications of Solar Cells 345
Mohd Imran Ahamed and Naushad Anwar
12.1 Introduction 345
12.2 An Overview on Photovoltaic Cell 348
12.2.1 History 348
12.2.2 Working Principle of Solar Cell 348
12.2.3 First-Generation Photovoltaic Cells:
Crystalline Silicon Form 351
12.2.4 Second-Generation Photovoltaic Cells:
Thin Film Solar Cells 352
12.2.5 Third-Generation Photovoltaic Cells 353
12.3 Applications of Solar Cells 354
12.3.1 Perovskite Solar Cell 354
12.3.2 Dye-Sensitized Solar Cell 355
12.3.3 Nanostructured Inorganic-Organic
Heterojunction Solar Cells (NSIOHSCs) 356
12.3.4 Polymer Solar Cells 357
12.3.5 Quantum Dot Solar Cell (QDCs) 358
12.3.6 Organic Solar Cells 360
12.4 Outlook and Summary 362
References 362
13 Challenges of Stability in Perovskite Solar Cells 371
Mutayyab Afreen, Jazib Ali and Muhammad Bilal
13.1 Introduction 371
13.2 Degradation Phenomena and Stability Measures
in Perovskite 373
13.2.1 Thermal Stability 373
13.2.2 Structural and Chemical Stability 375
13.2.3 Oxygen and Moisture 376
13.2.4 Visible and UV Light Exposure 378
13.3 Stability-Interface Interplay 379
13.3.1 Chemical Reaction at the Interface 379
13.3.2 Degradation on the Top Electrode 380
13.3.3 Hysteresis Phenomenon in PSC Devices 381
13.4 Effect of Selective Contacts on Stability 382
13.4.1 Electron-Transport Layers 382
13.4.2 Hole Transport Layers 384
13.4 Conclusion 387
References 387
14 State of the Art and Prospective of Solar Cells 393
Zahra Pezeshki and Abdelhalim Zekry
Acronyms 393
14.1 Introduction 396
14.2 State of the-Art of Solar Cells 396
14.2.1 Production Volume 400
14.2.2 Cost Breakdown 400
14.2.3 Main Technologies 401
14.2.3.1 Si Solar Cell Arrays 401
14.2.3.2 DSSCs 403
14.2.3.3 Photoanodes 404
14.2.3.4 C/Si Heterojunctions 405
14.2.3.5 a-C/Si Heterojunctions 407
14.2.3.6 Non-Fullerene Acceptor Bulk
Heterojunctions 407
14.2.3.7 a-Si 411
14.2.3.8 Perovskites 412
14.2.3.9 Metal-Halide–Based perovskites 413
14.2.3.10 Sn-Based Perovskites 416
14.2.3.11 Heavily Doped Solar Cells 421
14.2.3.12 PV Building Substrates 422
14.2.3.13 Solar Tracking System 423
14.2.3.14 Solar Concentrators 426
14.2.3.15 Solar Power Satellite 426
14.2.3.16 Roof-Top Solar PV System 428
14.2.3.17 Short-Wavelength Solar-Blind
Detectors 429
14.2.3.18 GCPVS 431
14.2.3.19 Microwave Heating in Si Solar
Cell Fabrication 432
14.2.3.20 Refrigeration PV System 434
14.2.3.21 Solar Collectors and Receivers 435
14.2.3.22 Solar Drying System 436
14.2.3.23 Water Networks With Solar PV Energy 437
14.2.3.24 Wind and Solar Integrated
to Smart Grid 438
14.2.3.25 Green Data Centers 442
14.3 Prospective of Solar Cells 445
14.4 Conclusion 447
References 448
15 Semitransparent Perovskite Solar Cells 461
Faiza Wahad, Zeeshan Abid, Sughra Gulzar,
Muhammad Shahid Aslam, Saqib Rafique,
Munazza Shahid, Muhammad Altaf
and Raja Shahid Ashraf
15.1 Introduction 462
15.2 Device Architectures 464
15.2.1 Conventional n-i-p Device Structure 465
15.2.2 Inverted p-i-n Device Structure 465
15.3 Optical Assessment 466
15.3.1 Average Visible Transmittance 466
15.3.2 Corresponding Color Temperature 467
15.3.3 Color Rendering Index 468
15.3.4 Transparency Color Perception 468
15.3.5 Light Management 471
15.4 Materials 474
15.4.1 Photoactive Layer 474
15.4.2 Charge Transport Layers (ETL and HTL) 479
15.4.3 Transparent Electrode 481
15.5 Applications 484
15.5.1 Building-Integrated Photovoltaics 484
15.5.2 Tandem Devices 486
15.6 Conclusion 492
References 492
16 Flexible Solar Cells 505
Santosh Patil, Rushi Jani, Nisarg Purabiarao, Archan Desai,
Ishan Desai and Kshitij Bhargava
16.1 Introduction 505
16.1.1 Need for Solar Energy Harnessing 505
16.1.2 Brief Overview of Generations of Solar Cells 506
16.1.3 Limitations of Solar Cells 508
16.1.4 What is Flexible Solar Cell (FSC)? 509
16.2 Materials for FSCs 510
16.2.1 Semiconductors 510
16.2.2 Substrates 512
16.2.3 Electrodes 513
16.2.4 Encapsulations 514
16.3 Thin-Film Deposition and Characterization 514
16.3.1 R2R Processing 515
16.3.2 Chemical Bath Deposition 516
16.3.3 Chemical Vapor Deposition 517
16.3.4 Dip Coating 518
16.3.5 Spin Coating 520
16.3.6 Screen Printing 521
16.4 Characterizations for FSCs 522
16.4.1 Material Characterization 523
16.4.2 Device Characterization 529
16.5 Issues in FSCs 531
16.6 Performance Comparison of RSCs and FSCs 532
16.7 Applications of Flexible Solar Cell 532
16.8 Conclusion 533
References 534
Index 537
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BISAC SUBJECT HEADINGS
TEC031010 : TECHNOLOGY & ENGINEERING / Power Resources / Alternative & Renewable
SCI024000 : SCIENCE / Energy
BUS070040 : BUSINESS & ECONOMICS / Industries / Energy
BIC CODES
THX: Alternative & renewable energy sources & technology
TGM: Materials Science
RNU: Sustainability
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