FeFET Devices, Trends, Technology and Applications

Preface xi

Acknowledgements xix

1 Scaling and Challenge of Si-Based CMOS: Past, Present, and Future 1
Shiromani Balmukund Rahi and Young Suh Song

1.1 Introduction to Si-Based CMOS Technology 2

1.2 Basic Concept of Transistor Scaling 3

1.3 Past Challenges in Scaling Si-Based CMOS 5

1.4 Present Challenges and Limitations of Si-Based CMOS 7

1.5 Representative Methods for Scaling MOSFET 8

1.6 Future Prospects and Innovations in Si-Based CMOS Technology 10

1.7 Navigating the Evolution of Si-Based CMOS Technology 10

1.8 The Future of Transistors: 2D FET 12

1.9 Conclusion 14

2 Ferroelectric Polymer-Based Field-Effect Transistor (FeFET) and its Applications 27
Dhrubojyoti Roy, Mohua Chakraborty, Dipankar Bandyopadhyay and Partho Sarathi Gooh Pattader

2.1 Introduction 28

2.2 Fabrication of Gate Dielectric Layer and FeFET 30

2.3 Working of FeFET 32

2.4 Applications of FeFET Device 33

2.5 Summary 46

3 Ferroelectric Applications in Novel Devices 57
Keshav Kumar and Umesh Chandra Bind

3.1 Introduction 58

3.2 General Concepts of Ferroelectrics 59

3.3 Ferroelectric Materials Processing for Device Applications 60

3.4 Advanced Application of Ferroelectric Materials 63

3.5 Summary and Outlook 67

4 Optimization of Hetero Buried Oxide Ferro TFET and Its Analysis 77
Sirisha Meriga and Brinda Bhowmick

4.1 Introduction 78

4.2 Mechanism of the Device and Method of Simulation 79

4.3 Results and Discussions 81

4.4 Conclusion 92

5 Ferroelectric Material-Based Field Effect Transistor and Its Applications 103
Avinash Kumar and Balwinder Raj

5.1 Introduction 104

5.2 Ferroelectric Material Properties and Advantages 106

5.3 Ferroelectricity in Nanoelectronics 109

5.4 Structures of Ferroelectric FET 111

5.5 Applications 116

5.6 Conclusion 119

5.7 Future Prospects for Nanoferroelectric Devices 120

6 Ferroelectric Tunnel FET: Next Generation of Classical Low Power CMOS Technology 131
Naima Guenifi, Shiromani Balmukund Rahi, Houda Chabane and Khadidja Dibi

6.1 Introduction 132

6.2 Implementation of Ferroelectric Material in Tunnel FET 133

6.3 Results and Analysis 135

6.4 Conclusion 142

7 Identification of Negative Capacitance in Ferroelectric in FET Devices 155
Umesh Chandra Bind, Shiromani Balmukund Rahi and Keshav Kumar

7.1 Introduction 156

7.2 Negative Capacitance 157

7.3 NC in Ferroelectrics 161

7.4 Ferroelectric Materials in Practice for NC 164

7.5 Evidence of NC in Ferroelectrics 168

7.6 Perspectives 172

7.7 Conclusion 173

8 Tunnel Field Effect Transistors and Their Application in Biosensors 185
K. Manikanta, Umakanta Nanda, Pratikhya Raut and Biswajit Jena

8.1 Introduction 186

8.2 What is Biosensor: Types and its Principle 187

8.3 Components of Biosensors 188

8.4 Application of FET in Biosensors 189

8.5 How TFET Works as a Biosensor and its Structure 190

8.6 Recent Structures of TFET-Based Bio-Sensors 191

8.7 Conclusion 193

9 Transparent Conducting Oxides: Introduction, Types, Deposition Techniques and Applications 205
Isha Arora and Rishi Kant

9.1 Introduction 206

9.2 Physical Characteristics of TCOs 207

9.3 Types of Transparent Conductors 212

9.4 Deposition Techniques 217

9.5 Sol-Gel Deposition 220

9.6 Applications of TCOs 223

9.7 Conclusion 227

10 Ferroelectric and FeFET Devices as Biosensors: Principle, Mechanisms and Applications in Health, Environmental, and Agricultural Monitoring 239
Umesh Chandra Bind, Keshav Kumar, Vimala Bind, Ajay Kumar and Jyoti Nishad

10.1 Introduction 240

10.2 Biosensors 241

10.3 Characteristics of Biosensors 244

10.4 Interaction Mechanism of Ferroelectric with Physical Stimuli 245

10.5 Working Principle of Biosensors 249

10.6 Biosensing Mechanism of Ferroelectrics 249

10.7 Ferroelectrics for Biosensing 252

10.8 Ferroelectrics in Health Monitoring 253

10.9 Ferroelectrics for Environmental Monitoring 257

10.10 Ferroelectrics for Agricultural Monitoring 258

10.11 FeFET Biosensors for Monitoring 258

10.12 Perspective 263

10.13 Conclusions 264

11 Ferroelectric Application in Recent Nanoscale Device with ITRS Roadmap 275
Shiromani Balmukund Rahi and Young Suh Song

11.1 Introduction to Ferroelectric Application 276

11.2 Ferroelectric Materials and Properties 276

11.3 Basic Scaling and ITRS Roadmap 279

11.4 Nanoscale Devices: Ultra-Thin-Body MOSFET, Gate-All-Around MOSFET, Gate, Channel, Source/Drain Engineering, Local High Doping for Better Subthreshold Swing 280

11.5 Nanoscale Devices with Ferroelectric Applications 281

11.6 Advantages and Potential Applications of Ferroelectric Materials 282

11.7 Positioning of Ferroelectric Technologies in the ITRS Roadmap 284

11.8 Possible Challenge in Future Ferroelectric Applications 285

11.9 Conclusion 286

12 Recent Electron Mobility Models for FeFET 297
Shiromani Balmukund Rahi and Young Suh Song

12.1 Introduction to Electron Mobility and FeFET 297

12.2 Classical Electron Mobility Models 298

12.3 Quantum Mechanical Models for Electron Mobility 300

12.4 Density Functional Theory (DFT) Approaches for Electron Mobility 302

12.5 Empirical Electron Mobility Models and Parameter Extraction Techniques 303

12.6 Challenges and Limitations in Modeling FeFET Electron Mobility 304

12.7 Future Directions and Emerging Trends in FeFET Electron Mobility Modeling 306

12.8 Conclusion 308

References 308

About the Editors 319

Index 321