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Full Product Details
Author: Mukesh Kumar Awasthi (Babasaheb Bhimrao Ambedkar University, India) , Reshu Gupta (University of Petroleum and Energy Studies (UPES), India)
Publisher: John Wiley & Sons Inc
Imprint: Wiley-Scrivener
ISBN: 9781394433575
ISBN 10: 1394433573
Pages: 464
Publication Date: 09 February 2026
Audience:
Professional and scholarly
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Professional & Vocational
Format: Hardback
Publisher's Status: Active
Availability: Awaiting stock 
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Table of Contents
Preface xvii 1 Artificial Intelligence in Heat Transfer and Fluid Dynamics: Innovations, Applications, and Future Directions 1 R. Sakthikala and R. Revathi 1.1 Introduction 2 1.2 Theoretical Foundations of Heat Transfer and Fluid Dynamics 4 1.3 Artificial Intelligence in Engineering: Methods and Techniques 5 1.4 Artificial Intelligence Applications in Heat Transfer 11 1.5 Artificial Intelligence in Fluid Dynamics 13 1.6 Practical Implementations 17 1.7 Challenges and Future Directions 19 1.8 Conclusion 21 2 Machine Learning Applications in Fluid Mechanics 23 A. Ahadi, P. Hosseini Baei and M. Sheikholeslami 2.1 Introduction 24 2.2 The Basics of Machine Learning 26 2.3 Fluid Mechanics Machine Learning Influenced by Physics 30 2.4 Methods for Modeling Turbulence 36 2.5 Machine Learning in Fluid Dynamics: Obstacles and Prospects 40 2.6 Summary 41 3 Artificial Intelligence-Enhanced Developments in Computational Fluid Dynamics 51 Tushar Sagar, Sachin Kumar, Dinesh Kumar Patel, Gaurav Nandan and Vipin Kumar Sharma 3.1 Introduction 52 3.2 An Overview of Artificial Intelligence in Computational Fluid Dynamics 55 3.3 Methodology of Artificial Intelligence-Driven Enhancement in Computational Fluid Dynamics 66 3.4 Discussion 77 3.5 Case Study 80 3.6 Conclusion 81 4 Artificial Neural Network-Based Analysis of Natural Convection in Ag-TiO©ü/H©üO Hybrid Nanoliquids 93 Madhavarao Kulkarni 4.1 Introduction 94 4.2 Mathematical Modeling 96 4.3 Methods of Solution 99 4.4 Results and Discussion 104 4.5 Conclusions 113 5 Artificial Intelligence-Based Optimization of Heat Transfer in Gyrotactic-Nanofluid Flow 117 Priyanka Chandra and Raja Das 5.1 Introduction 118 5.2 Mathematical Modeling 119 5.3 Numerical Method 122 5.4 Results and Discussions 123 5.5 Conclusions 137 6 Artificial Intelligence-Based Heat Exchanger Design and Optimization 141 Sachin Mishra, Raj Kumar, Shailendra Singh Rathore, Sakshi Saxena, Pushpendra Sharma, Shubhra Khare and Kuldeep Chauhan 6.1 Introduction 142 6.2 Artificial Intelligence-Based Heat Exchanger Design and Optimization 143 6.3 Principles of Heat Exchangers 143 6.4 Two-Pipe Heat Exchangers 145 6.5 Performance and Optimization Metrics 146 6.6 Worldwide Market for Heat Exchangers 146 6.7 Basic Equation of Heat Transfer 147 6.8 Designing Heat Exchangers Thermally 151 6.9 Issue with Thermal Design of Heat Exchanger 153 6.10 The Need for Artificial Intelligence in Heat Exchanger Design and Optimization 153 6.11 Artificial Intelligence in Heat Exchanger Design 154 6.12 Benefits of Artificial Intelligence in Heat Exchanger Design and Optimization 155 6.13 Artificial Intelligence Applications in Different Types of Heat Exchangers 156 6.14 Significance of Artificial Intelligence in Heat Exchanger Design 157 6.15 Key Aspects of Artificial Intelligence in Heat Exchanger Design 157 6.16 Applications of Artificial Intelligence in Heat Exchanger Design 159 6.17 Upcoming Developments and Trends 160 6.18 Heat Exchange Design 162 6.19 Innovation in Heat Exchanger Design 166 6.20 Challenges in Artificial Intelligence-Based Heat Exchanger Design 167 6.21 Conclusion 169 7 Artificial Intelligence-Driven Energy Optimization in Heating, Ventilation, and Air Conditioning Systems 177 G. Gandhimathi, C. Chellaswamy, S. Sridevi and Mohamed M. Awad 7.1 Introduction 178 7.2 Literature Review 183 7.3 Game Theory Structure of Liquid Flow 185 7.4 Liquid Flow of Fluid-Structural System 188 7.5 Result and Discussion 193 7.6 Conclusion 209 8 Artificial Neural Network Model for Radiative Heat Transfer in a Magnetized Tapered Stenosed Artery 213 Haris Alam Zuberi, Naveen Kumar and Nurul Amira Zainal 8.1 Introduction 214 8.2 Mathematical Modeling 217 8.3 Methodology: Implementation of a Physics-Informed Neural Network Model in MATLAB 221 8.4 Results and Discussion 223 8.5 Validation of a Physics-Informed Neural Network Model 229 8.6 Conclusions 231 8.7 Medical Applications and Future Prospects 232 9 Artificial Intelligence-Driven Flow Optimization in Renewable Energy Systems 237 Sachin Kumar, Vipin Kumar Sharma, Dinesh Kumar Patel, Gaurav Nandan and Tushar Sagar 9.1 Introduction 238 9.2 Artificial Intelligence in Wind Energy Systems 241 9.3 Artificial Intelligence in Hydroelectric Power Systems 254 9.4 Artificial Intelligence in Solar Power Systems 259 9.5 Challenges and Future Directions 264 9.6 Conclusion 267 10 Artificial Intelligence-Driven Flow Optimization for Enhanced Efficiency in Renewable Energy Systems 277 Kavita Sanjay Singh, V. Shanmugapriya, Siddharth Shankar Mishra and Manvendra Singh 10.1 Introduction 278 10.2 Fundamentals of Flow Dynamics in Renewable Energy Systems 280 10.3 Artificial Intelligence Technologies in Renewable Energy 286 10.4 Artificial Intelligence Models for Flow Prediction and Optimization 291 10.5 Optimizing Hydrodynamic Processes in Hydropower 294 10.6 Artificial Intelligence-Enhanced Solar Energy Systems 296 10.7 Challenges and Future Prospects 299 10.8 Conclusion 303 11 Artificial Intelligence for Flow Optimization in Renewable Energy Systems 307 Devanshi Srivastava and Adarsh Kumar Arya 11.1 Introduction 308 11.2 Artificial Intelligence, Deep Learning, and the Sustainable Development Goals 308 11.3 Analysis of Artificial Intelligence Technologies in Sustainable Power 310 11.4 Technology for Energy Efficiency 312 11.5 Recently Developed Artificial Intelligence-Powered Optimization Methods 316 11.6 Applications of Artificial Intelligence and Deep Learning for Ecological Well-Being 320 11.7 Using Artificial Intelligence and Deep Learning for Energy Efficiency in Smart Buildings 321 11.8 Application of Artificial Intelligence in Solid Waste Management Systems and Predictive Analysis Model in Solar Synergy 322 11.9 Ethical Concerns, Limitations, and Potential Biases in AI-Driven Environmental Solutions 323 11.10 Obstacles and Prospective Pathways 324 11.11 Conclusions 325 12 Physics-Informed Neural Networks for Exothermic Reactions in Porous Media 333 Pavan Patel and Saroj R. Yadav 12.1 Introduction 334 12.2 Mathematical Model 335 12.3 The Building Block of Physics-Informed Neural Networks 336 12.4 Experiments’ Results and Discussion 337 12.5 Conclusion 340 13 Machine Learning for Magnetohydrodynamic Nanofluid Flow: Artificial Neural Networks vs. Traditional Methods 343 B.C. Rout, Bijoylakshmi Boruah, Utpal Kumar Saha, Madhusudan Senapati, Sakambari Mishra, Vikash Kumar and Bhimanand Pandurang Gajbhare 13.1 Introduction 345 13.2 Problem Description 347 13.3 Results and Discussion 350 13.4 Conclusion 362 14 Case Studies of Artificial Intelligence in Industrial Fluid and Thermal Processes 365 Abdulhalim Musa Abubakar, Kiran Batool, Muhammad Asif and Baudilio Coto 14.1 Introduction 366 14.2 Artificial Intelligence Techniques in Fluid Flow and Heat Transfer 367 14.3 Artificial Intelligence in Chemical Processing Industries 369 14.4 Artificial Intelligence in Power Generation 373 14.5 Artificial Intelligence in Manufacturing and Electronic Components 374 14.6 Challenges, Limitations, and Recommended Solutions 377 14.7 Conclusion 381 15 Artificial Intelligence in Microfluidics and Nanofluidics 395 Ashish Mathur, Souradeep Roy and Rabab Fatima 15.1 Introduction 396 15.2 Case Study 400 15.3 Predictive Modeling of Fluid Behaviour 402 15.4 Real-Time Control Systems 402 15.5 Artificial Intelligence and Edge Computing for Real-Time Applications 403 15.6 Environmental Sensors 405 15.7 Challenges and Limitations 406 15.8 Future Directions 407 15.9 Regulatory and Ethical Considerations of Artificial Intelligence in Microfluidics 409 15.10 Conclusion 410 References 411 About the Editors 415 Index 417
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Author Information
Mukesh Kumar Awasthi, PhD is an Assistant Professor in the Department of Mathematics at Babasaheb Bhimrao Ambedkar University. He has published more than 125 research publications in journal and conference articles and book chapters, as well as ten books. His expertise lies in viscous potential flow, electro-hydrodynamics, magnetohydrodynamics, and heat and mass transfer. Reshu Gupta, PhD is an Associate Professor in the Applied Science Cluster at the University of Petroleum and Engineering Studies with more than 20 years of teaching experience. She has published several papers in international journals and conference proceedings and three books. Her research areas include fluid dynamics, differential equations, heat and mass transfer, nanofluids, entropy, and artificial neural networks.
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