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Full Description
A comprehensive resource offering actionable insights for designing and optimizing solar power systems with examples and case studies included throughout
Harnessing Solar Power: Designing and Optimizing Architectures for Sustainable Energy Systems delves into the intricate world of solar-powered systems, providing comprehensive insights into creating efficient architectures, streamlining workflows, and achieving sustainability. This book explores best practices and innovative techniques in solar design and management, covering the latest advancements in solar panel efficiency, storage solutions, and system integration. Readers will gain a deep understanding of how to build and optimize solar systems that meet environmental, economic, and social sustainability goals, with guidance on both technical and strategic dimensions.
Each chapter is structured to address critical areas, including system architecture, resource management, and the role of emerging technologies like AI and IoT in solar optimization. Practical examples and case studies demonstrate real-world applications.
Sample topics discussed in Harnessing Solar Power: Designing and Optimizing Architectures for Sustainable Energy Systems include:
Photovoltaic technology, solar thermal systems, and other emerging solar tech
Fundamental design principles for optimizing solar panel placement, orientation, and system scalability
Methods and benefits of integrating solar panels into building structures for aesthetics and efficiency
Essential components, such as inverters, wiring, and mounting structures, tailored for various applications
Guidelines for conducting site assessments, evaluating sunlight exposure, and determining system feasibility
Harnessing Solar Power: Designing and Optimizing Architectures for Sustainable Energy Systems serves as a transformative resource in the renewable energy sector, inspiring and equipping solar energy professionals, architects and urban planners, students, and policy makers and advocates to advance solar technology and adoption.
Contents
Notes on Contributors xxi
Preface xxxv
1 Basics of Solar Energy and Sustainable Applications 1
Namratha Bhandari, Sushma, and Santosh L. Gaonkar
1.1 Introduction to Solar Energy in the Context of Sustainability 1
1.2 Solar Energy Essentials and Photovoltaic Technology 2
1.3 Emerging Solar Technologies and Innovations 6
1.4 Design and Implementation of Solar Energy Systems 9
1.5 Smart Solar Systems: Role of Artificial Intelligence and IoT 12
1.6 Solar-Powered Architecture and Urban Integration 14
1.7 Environmental, Economic, and Social Benefits of Solar Energy 19
1.8 Challenges and Limitations in Solar Energy Adoption 22
1.9 Future Outlook and Research Directions 25
1.10 Conclusion 28
2 Introduction to Solar Energy and Sustainability 37
Sudarshana Banerjee, Surya Pratap Singh, Diwesh Kumar, and Shailesh Kumar Sarangi
2.1 Introduction 37
2.2 Fundamentals of Solar Energy 40
2.3 Sustainability and Solar Energy 45
2.4 Contribution to the SDGs 46
2.5 Technological Advancements and Innovations 48
2.6 Socioeconomic Impacts 49
2.7 Challenges and Limitations 50
2.8 Policy and Global Adoption 51
2.9 Future Outlook 51
2.10 Conclusion 52
3 Foundations of Solar Power Systems 59
Zahid Ahmad Thoker and Lovleen Marwaha
3.1 Introduction 59
3.2 Principle of Solar Power: Photovoltaics and Beyond 64
3.3 Designing Solar Architecture for Maximum Efficiency 68
3.4 Solar Energy Storage Solutions 70
3.5 System Components and Hardware Selection 79
3.6 Discussion 80
3.7 Conclusion 81
4 Corporate Social Responsibility and Solar Power: The Role of Solar Energy 87
Sunitha Sampathi, Pallavi Kale, Shital D. Godse, Nitiraj V. Kulkarni, and Ayathi Gadde
4.1 Introduction 87
4.2 The Business Case for Solar-Powered CSR Initiatives 88
4.3 Factors Affecting CSR in the Solar Energy Sector 90
4.4 Most Important Factors Influencing CSR Integration in Solar Energy Adoption 90
4.5 Corporate Strategies for Solar Energy Implementation in CSR Frameworks 93
4.6 Hurdles to Corporate Solar Adoption: Challenges and Barriers 95
4.7 Case Studies in Corporate Solar Adoption 99
4.8 Conclusion 102
5 Environmental Impact of Solar Power System 105
Sunitha Sampathi, Inaya R. Shaikh, Annapurna A. Batgiri, and Rukhsar E. Pathan
5.1 Introduction 105
5.2 Life Cycle Assessment (LCA) of Solar Energy 106
5.3 PV System Carbon Footprint 111
5.4 Utilizing Resources and Extracting Materials 113
5.5 Environmental Risks and Toxic Contaminants 115
5.6 Recycling and Waste Management Issues 118
5.7 Sustainable Design and Manufacturing Advances 122
5.8 Policy Perspectives and Regulatory Frameworks 125
5.9 Future Perspective: A Circular Solar Economy 129
5.10 Conclusion 131
6 AI and IoT Revolutionizing Solar Energy: Smarter, Greener, Better 149
A. Ashwini
6.1 Introduction to Solar Energy in Sustainable Development 149
6.2 Basics of Artificial Intelligence in Energy Systems 150
6.3 Synergy Between AI and IoT in Power Systems 152
6.4 Predictive Maintenances of Solar Panels 153
6.5 Real-Time Monitoring of Solar Installations 154
6.6 Smart Sensors and Actuators in PV Arrays 156
6.7 Peer to Peer Energy Trading Using Blockchain and IoT 158
6.8 Successful Deployments of AI-IoT Solar Systems 160
6.9 Sustainability and Carbon Footprint Reduction 161
6.10 Digital Twins for Solar Plant Simulation 162
6.11 Conclusion 164
7 Tamm Plasmon-Enhanced Organic Photodetectors for Narrowband Near-Infrared Sensing 167
Krishanu Poddar, Samir Kumar, and Partha Sona Maji
7.1 Introduction 167
7.2 Device Design and Structural Configuration 169
7.3 Simulation Results 172
7.4 Conclusion 174
8 AI and IoT in Solar Power Systems 179
Soumojit Maitra, Rik Mistri, Susmit Ray, Rezu Mistri, Piyal Roy, and Sanchita Ghosh
8.1 Introduction 179
8.2 Fundamentals of Solar Power Systems 182
8.3 IoT in Solar Power Systems 186
8.4 AI Applications in Solar Energy 191
8.5 Synergistic Integration of AI and IoT 196
8.6 Benefits and Impact Analysis 199
8.7 Challenges and Future Prospects 202
8.8 Conclusion 204
9 IoT and LPWA Technologies for Sustainable and Efficient Solar Energy Deployment in Bharat 209
Suresh Nanda Kumar, V. Sasirekha, and S. Chandrasekar
9.1 Introduction 209
9.2 Literature Review 211
9.3 Methodology 213
9.4 Analysis and Results 214
9.5 Discussion 222
9.6 Conclusion 223
10 Optimizing Workflows with Digital Tools 227
Devanshi Srivastava and Adarsh Kumar Arya
10.1 Introduction 227
10.2 Understanding Workflow Optimization 228
10.3 Identifying and Addressing Inefficiencies in Optimizing Workflows with Digital Tools 229
10.4 Essential Digital Tools for Workflow Enhancement 230
10.5 Enhancing Communication and Collaboration in Optimizing Workflows 232
10.6 Data Management and Performance Measurement in Optimized Workflows 234
10.7 Future Trends and Conclusion 235
11 Workflow Optimization and Management: AI and IoT in Solar Power Systems 241
D. Jasmine Priskilla
11.1 Introduction 241
11.2 AI and IoT in Solar Power Systems: A Synergistic Overview 244
11.3 AI-Driven Monitoring and Predictive Maintenance 246
11.4 IoT-Based Smart Grid and Energy Management 247
11.5 Workflow Optimization for Solar Power Systems 249
11.6 Case Studies and Real-World Implementations 251
11.7 Challenges and Future Trends 253
11.8 Conclusion 256
12 Enhancing Strategies for Rising Public Awareness and Acceptance of Solar Energy: A Socio-Behavioral Approach 259
K.J. Vinodini and Sandhiya Karunakaran
12.1 Introduction 259
12.2 Significance and Need for the Study 260
12.3 Review of Literature 260
12.4 Research Gap 264
12.5 Objectives 264
12.6 Methodology 265
12.7 Data Analysis 265
12.8 Findings 267
12.9 Recommendations 268
12.10 Conclusion 269
13 Leveraging Solar Energy in Corporate Social Responsibility as a Strategic Catalyst for Achieving Sustainability Goals 273
Kiruthiga Velmurugan
13.1 Introduction 273
13.2 Literature Review 275
13.3 Methodology 276
13.4 Conceptual Framework 277
13.5 Findings 278
13.6 Discussion 280
13.7 Conclusion 282
14 Smart Integration and Urban Solar Solutions for Sustainable Living in Smart Cities 285
A. Ashwini, G. Santhiya, and D. Menaka
14.1 Introduction to Smart Cities and Sustainable Living 285
14.2 Overview of Urban Solar Technologies 286
14.3 Synergy Between AI and IoT in Power Systems 288
14.4 Real-Time Data Analytics for Energy Optimization 290
14.5 Community Solar Projects 291
14.6 Urban Planning and Architectural Integration 292
14.7 Policy and Regulatory Frameworks 294
14.8 Financial and Economic Considerations 295
14.9 Environmental and Social Impacts 296
14.10 AI and Machine Learning in Solar Energy Management 297
14.11 Innovations from Developing Countries 299
14.12 Conclusion 300
15 Unlocking Solar Power: Rural Electrification with Special Reference to Pradhan Mantri Sahaj Bijli Har Ghar Yojana - Saubhagya for Sustainable Development 305
Sarulatha Neelakandan and V. Sasirekha
15.1 Introduction 305
15.2 Bridging the Gap - Renewable Energy Sources 306
15.3 About "Saubhagya" Scheme 307
15.4 Business Models in Rural Solar Electrification 308
15.5 Technological and Financial Innovations in Rural Electrification: Catalysts for Sustainable Energy Access 311
15.6 Financial Systems 312
15.7 Distribution and Maintenance Frameworks in Isolated Regions 313
15.8 Impact on Sustainable Development Goals 313
15.9 Challenges and Opportunities 314
15.10 Recommendations 315
15.11 Conclusion 316
16 Principles of Solar Power: Photovoltaics and Beyond 319
Somdatta Paul, Anindita Das, Soham Lodh, and Sunipa Roy
16.1 Introduction to Solar Energy 319
16.2 Photovoltaic Technology: Fundamentals and Advances 321
16.3 Solar Thermal Systems 327
16.4 Emerging Solar Technologies and Future Outlook 329
16.5 Conclusion 334
17 Environmental Impact of Solar Power Systems 339
Sudarshana Banerjee, Surya Pratap Singh, Diwesh Kumar, and Shailesh Kumar Sharangi
17.1 Introduction 339
17.2 Carbon Footprint of Solar PV Systems 341
17.3 Resource Consumption in Solar PV Manufacturing 345
17.4 Challenges in Solar Panel Recycling 347
17.5 Environmental Impacts of Solar Deployment 348
17.6 Incorporation of AI for Environmental Monitoring and Optimization 351
17.7 Circular Economy in the Solar PV Sector 352
17.8 Future Research and Sustainability Prospects 353
17.9 Conclusion 353
18 Life Cycle Management and System Upgrades 359
Sunitha Sampathi, Nishita Burade, Gayatri Sharma, and Sujatha Dodoala
18.1 Overview 359
18.2 HESS for Lifecycle Stability 361
18.3 Assessing Suns-Vmp Ineffectiveness 364
18.4 Predictive Maintenance and Smart Diagnosis 367
18.5 Cybersecurity Challenges and Strategies 371
18.6 Life Cycle Sustainability Assessment 374
18.7 Conclusion 375
19 Remote and Rural Area Solar-Powered Systems 385
Pooja Dehankar, Kashvi Chaturvedi, and Susanta Das
19.1 Introduction 385
19.2 Design, Deployment, and Effects of Solar-Powered Systems in Rural and Distant Locations 387
19.3 Photovoltaic (PV) Technology 390
19.4 Crucial Factors for Long-Term Sustainability 390
19.5 Benefits of Solar Power in Remote Areas 392
19.6 Challenges and Considerations 392
19.7 Future Directions 393
19.8 Conclusion 393
20 Material-Driven Performance in Cutting-Edge Solar Panels: A Quantitative Comparison of Efficiency and Power Yield 399
Princy Tyagi, Suman Pant, Shivani Pant, and Anshita Garg
20.1 Introduction 399
20.2 Results and the Performance of Solar Power Group Components 400
20.3 New Emerging Technologies 406
20.4 Conclusion 411
21 Renewable and Nonrenewable Energy Sources: A Brief Overview and Bibliometric Analysis 415
Kashvi Chaturvedi, Krutika Patre, Sunil Sankathala, Aditya Shrivastav, and Susanta Das
21.1 Introduction 415
21.2 Literature Review 416
21.3 Bibliometric Analysis 422
21.4 Conclusion 434
22 The Future of Solar Power: Innovations, Emerging Technologies, and Sustainable Integration 437
Achakkagari Shashidhar, S. Alekhya, and Parvez Ahmad
22.1 Introduction 437
22.2 Current State of Solar Power Technology 438
22.3 Innovations in Solar Cell Technology: Next-Generation Emerging Materials 440
22.4 Design and Infrastructure Advancements in Solar Photovoltaics 442
22.5 Energy Storage and Smart Integration 444
22.6 Sustainable Manufacturing and End-of-Life Solutions in Solar Technology 446
22.7 Solar Energy and SDGs 448
22.8 Implications for Policy and Global Development 448
22.9 Conclusion and Future Outlook 449
List of Abbreviations 449
References 450
Index 453
