+353-1-416-8900REST OF WORLD
+44-20-3973-8888REST OF WORLD
1-917-300-0470EAST COAST U.S
1-800-526-8630U.S. (TOLL FREE)

Graphene Field-Effect Transistors. Advanced Bioelectronic Devices for Sensing Applications. Edition No. 1

  • Book

  • 448 Pages
  • September 2023
  • John Wiley and Sons Ltd
  • ID: 5843029
Graphene Field-Effect Transistors

In-depth resource on making and using graphene field effect transistors for point-of-care diagnostic devices

Graphene Field-Effect Transistors focuses on the design, fabrication, characterization, and applications of graphene field effect transistors, summarizing the state-of-the-art in the field and putting forward new ideas regarding future research directions and potential applications. After a review of the unique electronic properties of graphene and the production of graphene and graphene oxide, the main part of the book is devoted to the fabrication of graphene field effect transistors and their sensing applications.

Graphene Field-Effect Transistors includes information on: - Electronic properties of graphene, production of graphene oxide and reduced graphene oxide, and graphene functionalization - Fundamentals and fabrication of graphene field effect transistors, and nanomaterial/graphene nanostructure-based field-effect transistors - Graphene field-effect transistors integrated with microfluidic platforms and flexible graphene field-effect transistors - Graphene field-effect transistors for diagnostics applications, and DNA biosensors and immunosensors based on graphene field-effect transistors - Graphene field-effect transistors for targeting cancer molecules, brain activity recording, bacterial detection, and detection of smell and taste

Providing both fundamentals of the technology and an in-depth overview of using graphene field effect transistors for fabricating bioelectronic devices that can be applied for point-of-care diagnostics, Graphene Field-Effect Transistors is an essential reference for materials scientists, engineering scientists, laboratory medics, and biotechnologists.

Table of Contents

Foreword xv

Preface xvii

1 2D Electronic Circuits for Sensing Applications 1
Diogo Baptista, Ivo Colmiais, Vitor Silva, Pedro Alpuim, and Paulo M. Mendes

1.1 Introduction 1

1.2 Graphene Inductors 3

1.2.1 Modeling of Graphene Inductors 4

1.3 Graphene Capacitors 5

1.3.1 Modeling Graphene Capacitors 8

1.4 2D Material Transistors 9

1.4.1 Most Common Topologies for Transistors 10

1.4.2 Modeling of 2D Materials-Based Transistors 11

1.5 2D Material Diodes 15

1.5.1 Most Common Topologies 16

1.5.2 Modeling of 2D Materials-Based Diodes 17

1.6 Graphene Devices 18

1.6.1 Graphene Frequency Multipliers 18

1.6.2 Graphene Mixers 18

1.6.3 Graphene Oscillators 19

1.6.3.1 Ring Oscillators 19

1.6.3.2 LC Tank Oscillators 19

1.7 Conclusion 19

References 20

2 Large Graphene Oxide for Sensing Applications 25
Jingfeng Huang, J. Amanda Ong, and I.Y. Alfred Tok

2.1 Graphene Oxide (GO) 25

2.2 GO as Biosensors 25

2.3 Large GO 26

2.4 Mechanism of Large GO via Modified Hummers Method 27

2.5 Large GO (Modified Hummers Method) Biosensors 28

2.6 Mechanism of Large GO via Reduced GO Growth 29

2.7 Large GO (Reduced GO Growth) Biosensors 34

2.8 Conclusion 38

2.9 Further Developments 38

References 39

3 Solution-Gated Reduced Graphene Oxide FETs: Device Fabrication and Biosensors Applications 43
Nirton C. S. Vieira, Bianca C. S. Ribeiro, Rodrigo V. Blasques, Bruno C. Janegitz, Fabrício A. dos Santos, and Valtencir Zucolotto

3.1 Introduction 43

3.2 Graphene, Graphene Oxide, and Reduced Graphene Oxide 45

3.2.1 Chemical Reduction 48

3.2.2 Thermal Reduction 49

3.2.3 Electrochemical Reduction 51

3.3 rGO-Based Solution-Gated FETs 52

3.3.1 Manufacturing Strategies 53

3.4 Applications of rGO SG-FETs as Biosensors 57

3.4.1 rGO Functionalization 59

3.4.2 Enzymatic Biosensors 60

3.4.3 Affinity Biosensors 61

3.4.4 Debye Length Screening and How to Overcome It 63

3.5 Final Remarks and Challenges 64

Acknowledgments 65

References 65

4 Graphene-Based Electronic Biosensors for Disease Diagnostics 71
Ahmar Hasnain and Alexey Tarasov

4.1 Introduction 71

4.1.1 A Promise for Diagnostics 71

4.1.2 Principle of Graphene FET Sensor 72

4.2 Device Fabrication Process 75

4.2.1 Graphene Synthesis 75

4.2.2 Graphene Transfer Over Substrates 76

4.2.3 Fabrication of GFET 77

4.2.4 New Developments 78

4.3 Functionalization and Passivation 78

4.3.1 Probe Molecules 79

4.3.2 Immobilization of Probe Molecules 80

4.3.3 Debye Length 81

4.3.4 Passivation 82

4.4 CVD GFETs for Diagnostics 83

4.4.1 Graphene-Based FET Biosensors for Nucleic Acids 83

4.4.2 Graphene-Based FET Biosensors for Antibody-Antigen Interactions 85

4.4.3 Graphene-Based FET Biosensors for Enzymatic Biosensors 87

4.4.4 Graphene-Based FET Biosensors for Sensing of Small Ions 90

4.5 Discussion 92

4.5.1 Summary 92

4.5.2 Challenges 92

4.5.3 Future Perspectives 93

References 93

5 Graphene Field-Effect Transistors: Advanced Bioelectronic Devices for Sensing Applications 103
Kyung Ho Kim, Hyun Seok Song, Oh Seok Kwon, and Tai Hyun Park

5.1 Introduction 103

5.1.1 Bioelectronic Nose Using Olfactory Receptor-Conjugated Graphene 106

5.1.2 Bioelectronics for Diagnosis Using Bioprobe-Modified Graphene 112

5.1.3 Biosensors for Environmental Component Monitoring Using Graphene 116

5.2 Conclusion 120

Acknowledgments 120

References 120

6 Thin-Film Transistors Based on Reduced Graphene Oxide for Biosensing 125
Kai Bao, Ye Chen, Qiyuan He, and Hua Zhang

6.1 Introduction 125

6.2 Working Principle of TFT-Based Biosensing 126

6.3 TFTs Based on rGO for Biosensing 128

6.3.1 Protein Detection 128

6.3.2 Metal-Ion Detection 131

6.3.3 Nucleic Acid Detection 134

6.3.4 Small Biomolecular Biosensor 135

6.3.5 Living-Cell Biosensor 137

6.3.6 Gas Detection 138

6.4 Conclusion 140

References 142

7 Towards Graphene-FET Health Sensors: Hardware and Implementation Considerations 149
Nicholas V. Apollo and Hualin Zhan

7.1 Introduction to Health Sensing 149

7.2 Graphene-FET in Liquid for Sensing 151

7.2.1 Graphene Transistors 153

7.2.2 Graphene Hall Structures in Liquid 156

7.2.3 Graphene Membrane Transistors 159

7.3 Device Implementation Considerations 160

7.3.1 Hardware and Instrumentation 160

7.3.2 Biostability and Biocompatibility 162

7.3.3 Medical Imaging Compatibility 163

References 164

8 Quadratic Fit Analysis of the Nonlinear Transconductance of Disordered Bilayer Graphene Field-Effect Biosensors Functionalized with Pyrene Derivatives 169
Sung Oh Woo, Sakurako Tani, and Yongki Choi

8.1 Introduction 169

8.2 Fabrication of Graphene-Based Field-Effect Biosensors 170

8.3 Fundamental Sensing Parameters of Graphene-Based Field-Effect Biosensors 173

8.4 Disordered Bilayer Graphene Field-Effect Biosensors Functionalized with Pyrene Derivatives 174

8.5 Quadratic Fit Analysis of the Nonlinear Transconductance of Disordered Bilayer Graphene Field-Effect Biosensors 177

8.6 Conclusion 181

Acknowledgment 181

References 182

9 Theoretical and Experimental Characterization of Molecular Self-Assembly on Graphene Films 185
Kishan Thodkar, Pierre Cazade, and Damien Thompson

9.1 Introduction 185

9.2 Experimental Tools to Characterize Molecular Functionalization of Graphene 186

9.2.1 Considering the Three Distinct Techniques Available for Functionalizing Graphene Are the Outcomes of the Three Functionalization Techniques Consistent, Similar, Reproducible Across all Three Techniques? 187

9.2.2 What Tools and Methods Are Available to Perform Such a Characterization of Molecular Self-Assembly Across the Nano to Macro Scale? 188

9.3 Atomistic Insights to Guide Molecular Functionalization of Graphene 196

References 203

10 The Holy Grail of Surface Chemistry of C VD Graphene: Effect on Sensing of cTNI as Model Analyte 207
Adrien Hugo, Teresa Rodrigues, Marie-Helen Polte, Yann R. Leroux, Rabah Boukherroub, Wolfgang Knoll, and Sabine Szunerits

10.1 Introduction 207

10.2 General Overview of C VD Graphene Production, Substrate Transfer and Characterization 210

10.3 Evaluation of Graphene Topographical Quality 212

10.4 CVD Graphene for FET-Based Sensing 214

10.4.1 Diazonium Chemistry on CVD Graphene 217

10.4.2 Pyrene Chemistry on CVD Graphene 220

10.5 Conclusion 225

References 226

11 Sensing Mechanisms in Graphene Field-Effect Transistors Operating in Liquid 231
Tilmann J. Neubert and Kannan Balasubramanian 231

11.1 Introduction 231

11.2 Field-Effect Operation in Liquid Compared to Operation in Air 232

11.3 Caveats When Operating FETs in Liquid 234

11.4 Graphene FETs in Liquid 235

11.5 Measurement Modes 236

11.6 Using FETs for Sensing in Liquid - Sensing Mechanisms 238

11.7 The Electrochemical Perspective 241

11.8 The GLI and pH Sensing 245

11.9 Detection of Nucleic Acids 246

11.10 Other Examples 247

11.11 Concluding Remarks 248

References 248

12 Surface Modification Strategies to Increase the Sensing Length in Electrolyte-Gated Graphene Field-Effect Transistors 251
Juliana Scotto, Wolfgang Knoll, Waldemar A. Marmisollé, and Omar Azzaroni

12.1 Introduction 251

12.2 Ion-Exclusion and Donnan Potential 253

12.3 Surface Modification with Polymer Films 255

12.4 Surface Modification with Lipid Layers 258

12.5 Surface Modification with Mesoporous Materials 260

12.6 Kinetic Cost of Extending the Sensing Length 262

12.7 Conclusions 265

References 266

13 Hybridized Graphene Field-Effect Transistors for Gas Sensing Applications 271
Radha Bhardwaj and Arnab Hazra 271

13.1 Introduction 271

13.2 Graphene 272

13.3 Graphene FET 272

13.4 Graphene in Gas Sensing 274

13.5 Graphene FET for Gas Sensing 275

13.6 Hybrid Graphene FET for Gas Sensing 277

13.7 Conclusion 281

Acknowledgments 281

References 281

14 Polyelectrolyte-Enzyme Assemblies Integrated into Graphene Field-Effect Transistors for Biosensing Applications 285
Esteban Piccinini, Gonzalo E. Fenoy, Wolfgang Knoll, Waldemar A. Marmisollé, and Omar Azzaroni

14.1 Introduction 285

14.2 Field-Effect Transistors Based on Reduced Graphene Oxide 286

14.3 Enzyme-Based GFET Sensors Fabricated via Layer-by-Layer Assembly 287

14.3.1 Layer-by-Layer (LbL) Assemblies of Polyethylenimine and Urease onto Reduced Graphene-Oxide-Based Field-Effect Transistors (rGO FETs) for the Detection of Urea 288

14.3.2 Ultrasensitive Sensing Through Enzymatic Cascade Reactions on Graphene-Based FETs 292

14.4 Conclusions 296

References 297

15 Graphene Field-Effect Transistor Biosensor for Detection of Heart Failure-Related Biomarker in Whole Blood 301
Jiahao Li, Yongmin Lei, Zhi-Yong Zhang, and Guo-Jun Zhang

15.1 Introduction 301

15.2 Experimental Systems and Procedures 304

15.2.1 Fabrication of GFET Sensor 304

15.2.2 Decoration of Platinum Nanoparticles 304

15.2.3 Surface Functionalization 305

15.2.4 Immunodetection in Whole Blood 305

15.2.5 Electrical Measurements 305

15.3 Sensing Principle of GFET for BNP Detection 306

15.4 Device Characterization 306

15.5 Sensing Performance 308

15.5.1 Stability and Reproducibility 308

15.5.2 Selectivity 309

15.5.3 Sensitivity 309

15.6 Clinical Application Prospects 311

15.7 Advantages, Limitations, and Outlook of the FET-Based BNP Assay 311

References 313

16 Enzymatic Biosensors Based on the Electrochemical Functionalization of Graphene Field-Effect Transistors with Conducting Polymers 317
Gonzalo E. Fenoy, Esteban Piccinini, Wolfgang Knoll, Waldemar A. Marmisollé, and Omar Azzaroni

16.1 Introduction 317

16.2 Functionalization of Graphene Transistors with Poly(3-aminobenzylamine-co-aniline) Nanofilms 318

16.3 Construction of Acetylcholine Biosensors Based on GFET Devices Functionalized with Electropolymerized Poly(3-amino-benzylamineco-aniline) Nanofilms 322

16.4 Glucose Detection by Graphene Field-Effect Transistors Functionalized with Electropolymerized Poly(3-amino-benzylamine-co-aniline) Nanofilms 327

16.5 Conclusions 332

References 333

17 Graphene Field-Effect Transistors for Sensing Stress and Fatigue Biomarkers 339
Biddut K. Sarker, Cheri M. Hampton, and Lawrence F. Drummy

17.1 Introduction 339

17.2 Molecular Biomarkers 341

17.3 Graphene Field-Effect Transistor Based Biosensors 343

17.3.1 Graphene 343

17.3.2 Structure of Graphene Field-Effect Transistors 345

17.3.3 Sensing Mechanism of GFET Biosensors 346

17.4 GFET Biosensor Fabrication 348

17.4.1 Graphene Production 348

17.4.2 Device Fabrication 349

17.4.3 Graphene Functionalization 350

17.5 GFET-Based Stress and Fatigue Biosensors 353

17.6 Flexible, Wearable GFET Biosensors, and Biosensor Systems 358

17.7 Current Challenges and Future Perspective 362

17.7.1 Debye Length Screening 362

17.7.2 Device-to-Device Variability 366

17.7.3 Short Lifetime and Reusability Issue 366

17.8 Conclusion 367

References 367

18 Highly Sensitive Pathogen Detection by Graphene Field-Effect Transistor Biosensors Toward Point-of-Care-Testing 373
Shota Ushiba, Takao Ono, Yasushi Kanai, Naruto Miyakawa, Shinsuke Tani, Hiroshi Ueda, Masahiko Kimura, and Kazuhiko Matsumoto

18.1 Introduction 373

18.2 Toward Detection of Pathogens by Mimicking Cell Surfaces 374

18.2.1 Introduction 374

18.2.2 Fabrication of Sialoglycan-Functionalized GFETs 375

18.2.3 Evaluation of Sialoglycan-Functionalized GFETs 375

18.3 Signal Enhancement in GFETs 377

18.3.1 Sensitivity Enhancement by Increasing Receptor Density 377

18.3.1.1 Case of Linkers 377

18.3.1.2 Basis for Evaluation of Linker-Based Performance Enhancement 378

18.3.1.3 Evaluation of Performance Enhancement by Linkers 378

18.3.2 Ultrasensitive Detection of Small Antigens by Open-Sandwich Immunoassay on GFETs 380

18.3.2.1 Principle of Open-Sandwich (OS) Immunoassay 380

18.3.2.2 Advantages of OS-IAs with GFETs 380

18.3.2.3 Antibody Fragments and Device Fabrication 381

18.3.2.4 OS-IAs on GFETs 382

18.3.2.5 OS-IAs on GFETs in Human Serum 382

18.3.3 Real-Time Measurement of Enzyme Reaction in Microdroplets Using GFETs and Its Application to Pathogen Detection 384

18.3.3.1 Introduction 384

18.3.3.2 Measurement Mechanism and Model Measurement System 385

18.4 Practical Issues: Baseline Drift and Inspection Methods 387

18.4.1 Drift Suppression and Compensation of GFET Biosensors 388

18.4.1.1 Drift Suppression in GFETs by Cation Doping 388

18.4.1.2 Drift Compensation by State-Space Modeling 390

18.4.2 Deep-Learning-Based Optical Inspection of GFETs 393

18.5 Conclusion 398

References 398

19 High-Performance Detection of Extracellular Vesicles Using Graphene Field-Effect Transistor Biosensor 405
Ding Wu, Yi Yu, Zhi-Yong Zhang, and Guo-Jun Zhang

19.1 What is Extracellular Vesicles 405

19.2 The Clinical Significance of Extracellular Vesicles 406

19.3 Introduction to Graphene Field-Effect Transistor Biosensor 406

19.4 GFET Biosensor for High-Performance Detection of Extracellular Vesicles 407

19.4.1 Detection of the Overall Level of Microvesicles Using GFET Biosensor 408

19.4.2 Specific Detection of Hepatocellular Carcinoma-Derived Microvesicles Using Dual-Aptamer Modified GFET Biosensor 409

19.4.3 Label-Free Detection of Cancerous Exosomes Using GFET Biosensor 410

19.5 Some Prospects for Graphene Field-Effect Transistor Biosensor 411

References 412

Index 417

Authors

Omar Azzaroni Universidad Nacional de La Plata, Argentina. Wolfgang Knoll Austrian Institute of Technology, Vienna, Austria.