Nanostructured Materials for Energy Applications
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Nanostructured Materials for Energy Applications: (Emerging Materials and Technologies)

Nanostructured Materials for Energy Applications: (Emerging Materials and Technologies)


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About the Book

This book demonstrates the necessity of novel methods for the development of nanostructured energy materials with improved characteristics for real life applications. It explores the prospective of nanoscale science to design and build up the device technology through novel nanoscale, photodetectors, photoconductor, photovoltaics, solar cells, batteries, supercapacitors, fuel cells, hydrogen generation and storage, and so forth. Various kinds of organic, inorganic, and organic-inorganic multilayer thin films photovoltaic solar cells devices are also addressed. Features: Discusses nanotechnology for energetic nano-structured materials and device applications developments. Combines all three types of nanostructured materials from organics, inorganics and perovskite and their device level applications. Articulates kinds of preparation methods for advanced energy related nano materials and their functionalization for the variety of devices. Explores the consequence of economizing and combination of 0D, 1D and 2D nanomaterials for the future energy demand. Establishes the wide range of applications of energetic nanomaterials in photovoltaics (including organic and inorganic). This book is aimed at graduate students and researchers in photovoltaics, batteries, and energy storage, and thermoelectrics.

Table of Contents:
Contents Foreword xv Preface xvii Editor Biographies xxiii Contributor List xxv Chapter 1 Introduction to nanostructured energy materials and their applicability 1 Abhay Kumar Singh 1.1 Introduction 1 1.2 Classification of nanomaterials 3 1.2.1 Zero‑dimensional materials 3 1.2.2 One‑dimensional materials 4 1.2.3 Two‑dimensional materials 5 1.2.4 Three‑dimensional materials 6 1.2.5 Nanostructures 7 1.2.6 Nanoparticles 8 1.2.7 Nanowires and nanotubes 9 1.2.8 Nanolayers or nanocoatings 9 1.2.9 Nanoporous materials 9 1.3 Strategies of nanomaterials synthesis 9 1.3.1 Chemical approaches 10 1.3.1.1 Sol–gel method 11 1.3.1.2 Hydro/solvothermal process 12 1.3.1.3 Polyol method 13 1.3.1.4 Sonochemical process 13 1.3.1.5 Microemulsion process 14 1.3.1.6 Chemical vapor deposition process 14 1.3.1.7 Atomic layer deposition (ALD) process 15 1.4 Physical methods 16 1.4.1 Mechanical approach 16 1.4.1.1 Ball milling method 16 1.4.1.2 Melt mixing approach 16 1.4.1.3 Inert‑gas technique 17 1.4.1.4 Pulse vapor deposition method 17 1.4.1.5 Pulsed laser deposition method 18 1.4.1.6 Electron beam vapor deposition method 18 1.4.1.7 Sputtering deposition method 18 1.4.1.8 Arc deposition method 19 1.4.1.9 Laser pyrolysis method 19 1.4.1.10 Flash spray pyrolysis method 20 1.5 Energetic applications of the nano materials 20 1.5.1 Photovoltaic solar cells 20 1.5.1.1 Silicon and thin‑film solar cells 21 1.5.1.2 Multijunction solar cells 22 1.5.1.3 Organic solar cells 23 1.5.1.4 Dye‑sensitized solar cells (DSSCs) 23 1.5.1.5 Quantum dots‑sensitized solar cells (QDSSCs) 25 1.5.2 Carbon nanotubes for optoelectronics 27 1.5.3 Graphene for optoelectronics 30 1.5.4 Transition‑metal dichalcogenides 31 1.6 Conclusions 33 References 33 Chapter 2 Photovoltaic energy material nano‑structuration and functionalization 45 Mohanraj Kumar, Sandhiya Murugan, S. Selvaraj, Mohd Shkir and Jih‑Hsing Chang 2.1 Introduction 45 2.2 Photovoltaic energy basics 46 2.2.1 How photovoltaic cells work 46 2.2.2 Types of photovoltaic cells 47 2.2.3 Efficiency and challenges 47 2.3 Nano‑structuration in photovoltaic materials 48 2.3.1 Principles of nano‑structuration 48 2.3.2 Benefits of nano‑structuration 49 2.3.3 Nano‑structured materials for photovoltaics 49 2.3.4 Techniques for nano‑structuration 49 2.4 Functionalization of photovoltaic materials 50 2.4.1 Introduction to functionalization 50 2.4.2 Purpose and advantages of functionalization 50 2.4.3 Types of functionalization in photovoltaics 50 2.4.4 Methods for functionalization 51 2.5 Types of nano‑structuration and functionalization 52 2.5.1 Surface nano‑structuration 52 2.5.1.1 Surface texturing 52 2.5.1.2 Nanoparticle deposition 52 2.5.2 Bulk nano‑structuration 53 2.5.2.1 Quantum dots 53 2.5.2.2 Nanowires 53 2.5.3 Chemical functionalization 54 2.5.3.1 Passivation layers 54 2.5.3.2 Dye sensitization 54 2.6 Methods for nano‑structuration and functionalization 54 2.6.1 Physical methods 54 2.6.1.1 Chemical vapor deposition (CVD) 55 2.6.2 Chemical methods 56 2.6.2.1 Sol‑gel process 56 2.6.2.2 Chemical bath deposition (CBD) 56 2.6.3 Hybrid methods 56 2.6.3.1 Electrochemical deposition 57 2.6.3.2 Atomic layer deposition (ALD) 57 2.7 Applications and case studies 57 2.7.1 Nano‑structured photovoltaic materials in solar cells 57 2.7.2 Functionalized photovoltaic materials for enhanced performance 57 2.7.3 Success stories and research developments 57 2.8 Challenges and future directions 58 2.8.1 Challenges in nano‑structuration and functionalization 58 2.8.2 Future trends and innovations 58 2.8.3 Sustainability and environmental considerations 58 2.9 Conclusion 58 References 59 Chapter 3 Zero‑dimensional (0D) nanomaterials and their energy applications 62 Abhay Kumar Singh 3.1 Overview 62 3.2 Nanomaterial unique features 63 3.2.1 Surface area 64 3.2.2 Quantum effects 64 3.2.3 Thermal and electrical conductivity 64 3.2.4 Magnetism 64 3.2.5 Mechanical properties 65 3.2.6 Catalytic support 65 3.2.7 Antimicrobial activity 65 3.3 Types of low‑dimensional nanomaterials 65 3.4 Zero‑dimensional (0D) nanomaterials 65 3.5 Zero‑dimensional nanomaterials in biosensing 66 3.5.1 0D Nanoparticles 67 3.5.2 0D QDs nanostructures 68 3.5.3 0D Fullerene 69 3.5.4 0D Nanospike 71 3.5.5 Carbon quantum dots (CQDs) 72 3.5.6 Graphene quantum dots (GQDs) 78 3.5.7 Inorganic quantum dots (IQDs) 80 3.5.8 Magnetic nanoparticles (MNPs) 84 3.6 Zero‑dimensional nanomaterials in photovoltaic 86 3.6.1 Significant features of photovoltaic cell construction 87 3.6.2 Zero‑dimensional perovskites 88 3.6.2.1 Zero‑dimensional halide perovskite structure 90 3.6.2.2 Zero‑dimensional halide perovskites crystal growth 91 3.6.3 Zero‑dimensional halide perovskites applications 91 3.6.3.1 Optoelectronics 91 3.6.3.2 Light‑emitting diodes 93 3.6.3.3 Photodetectors 94 3.6.3.4 Solar cells 95 3.6.3.5 Laser 97 3.7 Conclusions 98 References 98 Chapter 4 1D nanomaterials and their energy applications 111 Ziaul Raza Khan and Mohd Shkir 4.1 Introduction 111 4.2 1D nanomaterials 112 4.3 Development of 1D nanomaterials 112 4.3.1 Chemical vapor deposition 112 4.3.2 Chemical vapor transport 112 4.3.3 Metal organic chemical vapor deposition 113 4.3.4 Hydrothermal 113 4.3.5 Electrospinning 113 4.3.6 Template‑assisted synthesis 115 4.4 1D nanomaterials physical properties 115 4.4.1 Optical properties 115 4.4.2 Electrical properties 116 4.5 Applications of 1D nanomaterials for green energy harvesting 116 4.6 Conclusions and future prospects 119 References 119 Chapter 5 Two‑dimensional nanomaterials and their energy applications 123 Abhay Kumar Singh 5.1 Introduction 123 5.2 Classification of 2D materials 126 5.2.1 2D metal nanomaterials 127 5.2.2 Layered hydroxides 128 5.2.3 Metal‑organic framework 130 5.2.4 Xenes 132 5.2.5 Covalent organic framework 135 5.3 2D materials energetic applications 137 5.4 2D materials for photovoltaic application 138 5.4.1 2D perovskite solar cells (PSCs): a brief outline 139 5.4.2 Monoelemental 2D materials for PSCs 140 5.4.3 Transparent conductive electrode (TCE) 142 5.4.4 Electron transporting layer (ETL) 142 5.4.5 Perovskite layer (PL) 143 5.4.6 HTL 147 5.4.7 Conductive back electrode 148 5.5 Dye‑sensitized solar cells (DSSCs) 151 5.5.1 2D‑NL‑based DSSCs 152 5.5.2 Graphene‑based DSSCs 153 5.5.3 TiO2‑based DSSCs 153 5.5.4 MXene‑based DSSCs 155 5.5.5 Black phosphorus (BP)‑based DSSCs 155 5.5.6 Chalcogen 2D‑NL‑based DSSCs 157 5.6 Conclusions 158 References 159 Chapter 6 3D Nanomaterials and their energy applications 175 Valparai Surangani Manikandan, Arun Thirumurugan, Krishnamoorthy Shanmugaraj, Dhandayuthapani Thiyagarajan, Ranjith Kumar Poobalan, Natarajan Chidhambaram, Nagarajan Dineshbabu, Kalpana Kalyanasundaram, and Dhanabalan Shanmuga Sundar 6.1 Introduction 175 6.2 Preparation of 3D nanomaterials 179 6.3 3D Nanomaterials for energy storage 188 6.3.1 3D nanomaterials for supercapacitors 188 6.3.2 3D Nanomaterials for batteries 196 6.3.3 3D nanomaterials for energy conversionelectrocatalytic water splitting (HER, OER) 204 6.4 Conclusion 211 Acknowledgments 212 References 212 Chapter 7 Advanced nanostructured thin films of organic materials for photovoltaic solar cells applications 216 M. Aslam Manthrammel and Mohd Shkir 7.1 Introduction 216 7.1.1 Classification of solar cells 216 7.1.2 Next‑generation (third‑generation) solar cells 216 7.1.3 Dye‑sensitized and quantum dot‑sensitized solar cells (DSSCs and QDSSCs) 217 7.1.4 Perovskite solar cells (PSCs) 219 7.2 Organic solar cells (OSCs) 220 7.2.1 Working principle of OSCs 220 7.2.2 Materials 221 7.2.3 Device architectures 221 7.2.3.1 Bilayer OSC fabrication or planar heterojunction architecture 221 7.2.3.2 Bulk heterojunction (BHJ) configuration 222 7.2.3.3 Inverted geometry 223 7.2.4 Working mechanism 224 7.2.4.1 Photon absorption 224 7.2.4.2 The exciton diffusion 225 7.2.4.3 Charge dissociation and transportation 226 7.3 Solar cell characteristics 226 7.4 Recent advancements in the OSCs 227 7.4.1 Efficiency improvements 227 7.4.2 Stability enhancements 228 7.4.3 Tandem (multi‑junction) designs 228 7.4.4 Non‑fullerene acceptors 228 7.4.5 Scalable manufacturing 228 7.5 Summary 228 References 229 Chapter 8 Advances of nanostructured thin films for their applications in solar cells 231 Arun Kumar Senthilkumar, Mohanraj Kumar, Jih‑Hsing Chang, Sandhiya Murugan, Mohd Taukeer Khan and Mohd Shkir 8.1 Introduction 231 8.1.1 Motivation and objectives 231 8.1.2 Overview of the chapter 232 8.2 Solar cells 232 8.2.1 Working principal of a solar cells 233 8.2.2 Electrical characteristic parameter of a solar cells 234 8.2.2.1 Short‑circuit current (JSC) 234 8.2.2.2 Open‐circuit voltage (VOC) 235 8.2.2.3 Fill factor (FF) 235 8.2.2.4 Power conversion efficiency (ɳ) 236 8.3 Nanostructured thin films: concept, classification, and fabrication methods 236 8.3.1 Concept and classification of nanostructured thin films 236 8.3.2 Fabrication methods of nanostructured thin films 237 8.3.2.1 Mechanical milling 237 8.3.2.2. Vapor deposition 237 8.3.2.3 Laser ablation and electron beam lithography 238 8.3.2.4 Spray pyrolysis 238 8.3.2.5 Co‑precipitation and hydrothermal method 238 8.3.2.6 Sol–gel method 239 8.3.2.7 Inkjet printing 239 8.3.2.8 Spin coating process 239 8.4 Properties and performance of nanostructured thin‑film solar cells 240 8.4.1 Optical properties 240 8.4.2 Electrical properties 240 8.4.3 Thermal properties 241 8.4.4 Mechanical properties 241 8.4.5 Structural and morphological properties 242 8.5 Applications of nanostructured thin films in solar cells 242 8.5.1 Nanostructured thin films for crystalline silicon solar cells 243 8.5.2 Nanostructured thin films for thin‑film solar cells 244 8.5.2.1 Amorphous silicon solar cells 244 8.5.2.2 Cadmium telluride solar cells 246 8.5.2.3 Copper indium gallium selenide solar cells 247 8.5.2.4 Perovskite solar cells (PSCs) 248 8.5.2.5 Organic solar cells 249 8.5.2.6 Dye‑Sensitized solar cells 251 8.5.2.7 Quantum dot solar cells (QDSCs) 252 8.6 Conclusion 253 References 254 Chapter 9 Organic–inorganic materials‑based advanced nanostructured thin films for photovoltaic solar cell applications 262 Ashwani Kumar and Mohd Shkir 9.1 Introduction 262 9.2 Heterojunction thin‑film solar cells 264 9.3 CDTE thin‑film solar cells 265 xiv Contents 9.4 CIGS thin‑film solar cells 267 9.5 Perovskite solar cells 268 9.6 Operational principle of hybrid perovskite 269 9.7 Architectures of perovskite solar cells 270 9.8 The compact metal oxide blocking layer 270 9.9 Electron transport layer 271 9.10 Absorbing perovskite layer 272 9.11 The hole transport layer 272 9.12 The electrode contacts 273 9.13 Tandem solar cells 273 9.14 Perovskite‑silicon tandem solar cells 274 9.15 Tandem silicon solar cells with cigs crystal 276 9.16 Quantum dot tandem solar cells 277 9.17 Organic‑inorganic hybrid tandem solar cells 277 9.18 Conclusion 279 References 279 Chapter 10 Quantum dots/nanoparticles for solar energy applications 283 Ashwani Kumar, Ziaul Raza Khan, Mohd Shkir and Thamrah Alshahrani 10.1 Introduction 283 10.2 Working mechanisms of solar cell 284 10.3 Different generation’s solar cells 284 10.4 Lead‑based quantum dots 287 10.5 Lead halide perovskite quantum dots 290 10.6 Fabrication techniques of perovskite solar cells 295 10.7 Cadmium‑based quantum dots solar cells 297 10.8 Conclusion 301 References 301 Chapter 11 Challenges and future prospects 310 Mohanraj Kumar, Mohd Shkir and Abhay Kumar Singh Acknowledgments 312 References 312 Index 313

About the Author :
Abdullah M. Al‑Enizi obtained his Ph.D. in 2013 jointly from King Saud University (KSA) and the University of Texas at Austin (USA), and then joined the Department of Chemistry at King Saud University as an Assistant Professor. His research interests include polymeric materials, porous nanomaterials, catalysis, and electrochemistry. He has authored more than 200 publications of high impact and holds 3 US patents. Dr. Enizi’s Scopus citation count is 5799, and he is a leading researcher in Advanced Polymers and Hybrid Nanomaterials. He is also a life member of several international scientific societies. Mohd Ubaidullah works as an Assistant Professor in the Department of Chemistry, College of Science, King Saud University, Riyadh, Saudi Arabia. He obtained his Ph.D. and worked at the Department of Chemistry, Jamia Millia Islamia, New Delhi, India. Dr. Ubaidullah has published more than 90 research papers in journals of international repute. His research mainly focuses on energy, water treatment, catalysis, optoelectronics, and sensors. Mohd Shkir is an Associate Professor at the Department of Physics, King Khalid University, Abha, Saudi Arabia. He has published over 650 research papers of high‑impact international and national journals with over 13900 citations, h‑index‑54, i10‑index 395 and published four US patents [US‑20230221273‑A1, US‑20230212403‑A1, US‑20230356162‑A1, US‑20230357047‑A1] and one EU patent [ES2527976 (A1)―2015‑02‑02]. One new patent has been filed to United States Patent and Trademark Office (USPTO). He is leading a research group “Investigation on Novel Class of Materials (INCM) at KKU.” He was born in Madhoupur, Pilibhit, UP, India in 1982. His scientific interest focuses on optics, nanotechnology, and thin‑film fabrications for optoelectronic device applications, which combine experimental and theoretical techniques. He is also working on the development of materials for energy applications, fabrication of new systems and devices for future applications, and the determination of various electro‑optical properties using computational techniques. He is currently working on nanosynthesis and thin‑film fabrication of different kinds of materials for biomedical, optoelectronic, and radiation detection, supercapacitors, photodetectors, and gas sensors applications. Abhay Kumar Singh works as a Professor in the Faculty of Engineering and the Built Environment Dean’s Office, University of Johannesburg, Johannesburg, South Africa. He has taught undergraduate courses and conducted research at Mahatma Gandhi Kashi Vidyapith, Varanasi, India, and both undergraduate and postgraduate levels at Lovely Professional University, India. He worked as a Brain Korea 21 Postdoctoral Fellow in the Department of Electrical Engineering and Department of Physics (jointly) at Incheon National University, South Korea. He was also a Dr. D.S. Kothari Postdoctoral Fellow in the Department of Physics at the Indian Institute of Science, Bangalore, India. His current research interests include chalcogenide photovoltaic solar cells, chalcogen‑nanocomposites, chalcogenide metallic/non‑metallic multicomponent alloys, TMD materials, and thermal, optical, and electrical characterizations. He successfully introduced two new series of chalcogenide glasses, Se‑Zn‑In and Se‑Zn‑Te‑In, in 2009 and 2010, respectively, as well as SZSMWCNT and SZS‑GF in 2012. His experimental findings have been demonstrated in more than 42 technical research publications in reputed international journals, along with two international book chapters and Two books.


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Product Details
  • ISBN-13: 9781040440087
  • Publisher: Taylor & Francis Ltd
  • Publisher Imprint: CRC Press
  • Language: English
  • ISBN-10: 1040440088
  • Publisher Date: 13 Nov 2025
  • Binding: Digital (delivered electronically)
  • Series Title: Emerging Materials and Technologies


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