Yong Zhu & Nanshu Lu 
Mechanics of Flexible and Stretchable Electronics [EPUB ebook] 

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Discover a comprehensive overview and advances in mechanics to design the cutting edge electronics

Soft electronics systems, which include flexible and stretchable electronics, are an area of technology with the potential to revolutionize fields from healthcare to defense. Engineering for flexibility and stretchability without compromising electronic functions poses serious challenges, and extensive mechanics and engineering knowledge is required to meet these challenges. Mechanics of Flexible and Stretchable Electronics introduces a range of soft functional materials and soft structures and their potential applications in the construction of soft electronics systems. Its detailed attention to the mechanics of these materials and structures makes it an indispensable tool for scientists and engineers at the cutting edge of electronics technology.

Mechanics of Flexible and Stretchable Electronics readers will also find:


  • A detailed summary of recent advances in the field

  • Detailed treatment of structures including kirigami, serpentine, wrinkles, and many more

  • A multidisciplinary approach suited to a varied readership


Mechanics of Flexible and Stretchable Electronics is ideal for electronics and mechanical engineers, solid state physicists, and materials scientists, as well as the libraries that support them.

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表中的内容

Preface xiii

Part I Materials 1

1 Extreme Mechanics of Hydrogels Toward In Situ Hydrogel Bioelectronics 3
Tsz H. Wong, Xuanhe Zhao, and Shaoting Lin

1.1 Introduction 3

1.2 Extreme Properties of Hydrogels by Polymer Network Design 5

1.3 Stretchable Hydrogel Conductors 14

1.4 Electrochemical Hydrogel Biosensors 18

1.5 Flexible Hydrogel Biobattery 20

1.6 Concluding Remarks 23

2 Multiscale Mechanics of Metal Nanowire-Based Stretchable Electronics 37
Shuang Wu and Yong Zhu

2.1 Introduction 37

2.2 Metal NW-Based Flexible and Stretchable Electronics 38

2.3 Mechanics of Individual NWs 39

2.4 Interfacial Mechanics of the NW-Polymer Interface 45

2.5 Mechanical Design of Stretchable Structures 54

2.6 Concluding Remarks 58

3 Liquid Metal-Based Electronics 69
Carmel Majidi

3.1 Introduction 69

3.2 LM Architectures 71

3.3 Mechanics and Modeling 76

3.4 Open Challenges and Future Directions 81

4 Mechanics of Two-Dimensional Materials 87
Olugbenga Ogunbiyi and Yingchao Yang

4.1 Introduction 87

4.2 Nanoindentation Method 90

4.3 AFM-Enabled Nanoindentation 93

4.4 In Situ Indentation in SEM 108

4.5 Micro-/Nano-mechanical Devices 111

4.6 Piezoelectric Tube-Driven Testing in TEM 120

4.7 Bulge Testing 121

4.8 Electrostatic Force Triggered Drum Structure 124

4.9 Phonon Dispersion Measurement 125

4.10 Summary 126

5 Mechanics of Flexible and Stretchable Organic Electronics 139
Abdullah Al Shafe and Brendan T. O’Connor

5.1 Introduction 139

5.2 Mechanical Characterization Methods 140

5.3 Material Design 145

5.4 Device Design 153

5.5 Applications 156

5.6 Conclusion 159

Part II Design and Manufacturing 171

6 Structural Design of Flexible and Stretchable Electronics 173
Zhaoqian Xie, Zichen Zhao, and Raudel Avila

6.1 Introduction 173

6.2 Design of Planar Stretchable and Flexible Structures 174

6.3 Design of Three-Dimensional Flexible Electronic Structures 189

6.4 Design of Protective Structures for Flexible Electronic Devices 193

7 Laser-Based Fabrication Process Development for Flexible and Stretchable Electronics 207
Jung Jae Park, Minwoo Kim, and Seung Hwan Ko

7.1 Introduction 207

7.2 Representative Laser-Based Fabrication Process 208

7.3 Applications Based on Laser Fabrication 211

7.4 Perspectives and Conclusion 225

8 Electrospinning Manufacturing of Stretchable Electronics 235
Yinhui Li, Kan Li, Yunlei Zhou, and Yong An Huang

8.1 Background 235

8.2 High-Precision Manufacturing 236

8.3 Electrospinning Stretchable Structure 243

8.4 Application in Stretchable Electronics 247

8.5 Conclusions 254

9 Mechanics-Guided 3D Assembly of Flexible Electronics 265
Guoquan Luo, Jianzhong Zhao, Xu Cheng, and Yihui Zhang

9.1 Introduction 265

9.2 Design Strategies of Mechanics-Guided Assembly 266

9.3 Mechanics Modeling and Analyses of the 3D Assembly 275

9.4 Applications of 3D Flexible Electronics 284

9.5 Concluding Remarks 287

10 Harnessing Wrinkling and Buckling Instabilities for Stretchable Devices and Healthcare 293
Yao Zhao, Fangjie Qi, Haoze Sun, Yanbin Li, Haitao Qing, and Jie Yin

10.1 Introduction 293

10.2 Structural Designs and Mechanics 294

10.3 Applications in Stretchable Devices 300

10.4 Applications in Healthcare 306

10.5 Conclusion and Outlook 311

Part III Applications 319

11 Spherical Indentation Behavior of Soft Electronics 321
Changxian Wang, Zequn Cui, and Xiaodong Chen

11.1 Spherical Indentation of the Semi-infinite Solid 321

11.2 Applications in a Force-Softness Bimodal Sensor Array for Human Body Feature Identification 328

11.3 Applications in a Self-Locked Young’s Modulus Sensor for Quantifying the Softness of Swollen Tissues in the Clinic 336

11.4 Conclusions 343

12 Mechanics of Wet Adhesion 345
Jiawei Yang and Ruobing Bai

12.1 Introduction 345

12.2 Characterization of Adhesion 346

12.3 General Principles for Strong Wet Adhesion 347

12.4 Methods for Strong Wet Adhesion 354

12.5 Mechanics of Wet Interfaces 357

12.6 Summary and Outlook 362

13 Electromechanics of Soft Resistive and Capacitive Tactile Sensors 373
Zhengjie Li, Sangjun Kim, Zheliang Wang, Zhengtao Zhu, and Nanshu Lu

13.1 Introduction 373

13.2 Resistive Tactile Sensors 378

13.3 Capacitive Tactile Sensors 399

13.4 Resistive-Capacitive Hybrid Response Tactile Sensors 415

13.5 Conclusion and Outlook 418

14 Active Mechanical Haptics Constructed with Curved Origami 431
Zhuang Zhang and Hanqing Jiang

14.1 Introduction 431

14.2 Stiffness Tuning via Curved Origami 432

14.3 Theoretical Modeling and Analysis of Curved Origami 434

14.4 Closed-Loop Design and System Integration of Origami 438

14.5 In-hand Haptic Device 440

14.6 Stiffness Perception via Active Pressing 443

14.7 Body-Centered Stepping Device 444

14.8 Whole-Body Stiffness Perceptions 447

14.9 Discussion 448

15 Mechanics of Transient Electronics 453
Ankan Dutta and Huanyu Cheng

15.1 Introduction 453

15.2 Hydrolysis of Semiconducting Materials 455

15.3 Model of Reactive Diffusion for Transient Materials 457

15.4 Dissolution of the Device with Bi-layered Structures 461

15.5 Conclusion 467

Acknowledgments 468

References 468

Index 473

关于作者

Yong Zhu, Ph D, is the Andrew A. Adams Distinguished Professor in the Department of Mechanical and Aerospace Engineering at North Carolina State University (NCSU). He received his Ph.D. degrees from Northwestern University. His work has been recognized with a number of awards including James R. Rice Medal from the Society of Engineering Science, Bessel Research Award from the Alexander von Humboldt Foundation, Zdeněk P. Bažant Medal and Gustus L. Larson Memorial Award from ASME.
Nanshu Lu, Ph D, is Full Professor at the University of Texas at Austin. She received her B.Eng. from Tsinghua University, Beijing, Ph.D. from Harvard University, and then Beckman Postdoctoral Fellowship at UIUC. She has been named 35 innovators under 35 by MIT Technology Review (TR 35) and i CANX/ACS Nano Inaugural Rising Star. She has received US NSF CAREER Award, US ONR and AFOSR Young Investigator Awards, 3M non-tenured faculty award, and the ASME Applied Mechanics Division Thomas J.R. Hughes Young Investigator Award. She has been selected as one of the five great innovators on campus and five world-changing women of the University of Texas at Austin.

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语言 英语 ● 格式 EPUB ● 网页 887 ● ISBN 9783527842292 ● 文件大小 133.5 MB ● 编辑 Yong Zhu & Nanshu Lu ● 出版者 Wiley-VCH ● 国家 DE ● 发布时间 2024 ● 版 1 ● 下载 24 个月 ● 货币 EUR ● ID 9700295 ● 复制保护

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