Table of Contents

Table of Contents:

Chapter 1: Nanomaterials for static and dynamic flow supercapacitors

1.0 Introduction

1.1 Classification based on working principle

1.2 Classification based on morphology

1.3 Materials used as substrates in flexible supercapacitors

1.4 Materials used for making the electrode

1.5 Materials used as the electrolyte

1.6 Electrochemical flow capacitor

1.7 Conclusion

Chapter 2: Emerging technological advancements in thermal energy storage

2.1 Introduction

2.2 TES Technologies

2.3 Latent heat storage systems

2.4 Applications of sensible thermal energy storage

2.5 Sensible thermal energy storage

2.6 Latent heat energy storage

Chapter 3: Quantum dots as an efficient supercapacitor for modern world

3.1 Introduction

3.2 Synthesis of carbon quantum dots

3.3 Synthesis of Graphene quantum dots

3.4 Carbon quantum dots for supercapacitors

3.5 Graphene quantum dots for supercapacitors

3.6 Conclusion

Chapter 4: Importance of redox active electrolyte for the next generation energy storage system

4.1 Introduction

4.2 Charge storage principles of Redox electrolytes contains ECs

4.3 Mechanism of diffusion, adsorption, and kinetics of redox electrolyte

4.4 Categories of redox electrolyte

4.4.1 Aqueous systems

4.4.1.1 Anion redox electrolytes

4.4.1.2 Cation redox electrolytes

4.4.1.3 Neutral redox electrolytes

4.4.2 Non-aqueous electrolyte

4.4.2.1 Ionic liquid based redox electrolytes

4.4.2.2 Gel polymer based redox electrolytes

4.5 Dual redox electrolyte non-flow system

4.6 Catholyte and anolyte based redox electrolyte

4.7 Conclusion

Chapter 5: Conclusion on current trends in energy storage system

5.1 Mechanical energy storage

5.2 Heat energy storage

5.3 Electrochemical energy storage

5.4 Electromagnetic energy storage

5.5 Chemical energy storage

5.6 Hydrogen energy storage

5.7 Synthetic gas

5.8 Solar fuels

5.9 Future aspects of energy storage systems