Graphene for Post- Moore Silicon Optoelectronics Graphene for Post Moore ‐ Silicon Optoelectronics Yang Xu, Khurram Shehzad, Srikrishna Chanakya Bodepudi, Ali Imran, and Bin Yu Authors All books published by WILEY- VCH are carefully produced. Nevertheless, authors, editors, Prof. Yang Xu and publisher do not warrant the information Zhejiang University contained in these books, including this book, to be School of Micro- Nano Electronics free of errors. Readers are advised to keep in mind No. 388, YuHangTang Rd. that statements, data, illustrations, procedural Xihu District details or other items may inadvertently be 310027 Hangzhou inaccurate. China Library of Congress Card No.: applied for Dr. Khurram Shehzad British Library Cataloguing- in- Publication Data: Zhejiang University A catalogue record for this book is available School of Micro- Nano Electronics from the British Library. No. 388, YuHangTang Rd. Bibliographic information published by the Xihu District Deutsche Nationalbibliothek 310027 Hangzhou The Deutsche Nationalbibliothek China lists this publication in the Deutsche Dr. Srikrishna Chanakya Bodepudi Nationalbibliografie; detailed bibliographic data are available on the Internet at http:// Zhejiang University dnb.d- nb.de. School of Micro- Nano Electronics No. 388, YuHangTang Rd. © 2023 WILEY- VCH GmbH, Boschstr. Xihu District 12, 69469 Weinheim, Germany 310027 Hangzhou All rights reserved (including those of China translation into other languages). No part of Dr. Ali Imran this book may be reproduced in any form – by Zhejiang University photoprinting, microfilm, or any other means – School of Micro- Nano Electronics nor transmitted or translated into a machine No. 388, YuHangTang Rd. language without written permission from the Xihu District publishers. Registered names, trademarks, etc. 310027 Hangzhou used in this book, even when not specifically China marked as such, are not to be considered unprotected by law. Prof. Bin Yu Print ISBN 978- 3- 527- 35181- 7 Zhejiang University ePDF ISBN 978- 3- 527- 84099- 1 School of Micro- Nano Electronics ePub ISBN 978- 3- 527- 84100- 4 No. 388, YuHangTang Rd. oBook ISBN 978- 3- 527- 84101-1 Xihu District 310027 Hangzhou Typesetting Straive, Chennai, India China Cover Images: © GrAl/Shutterstock v Contents Preface ix Acknowledgments xi Biography xii 1 Graphene for Silicon Optoelectronics 1 1.1 Introduction 1 1.2 Optical Absorption 2 1.3 Emergence of Graphene in Silicon Optoelectronics 3 1.4 Photodetection in Graphene 4 1.4.1 Performance Metrics 5 1.4.2 Photovoltaic Effect 5 1.4.3 Photoemission in Graphene Schottky Junctions 6 1.4.4 Thermionic Emission in Graphene-based Interfaces 7 1.4.5 Hot Electron-based Photodetection 9 1.4.5.1 Photothermoelectric Effect (PTE) 10 1.4.5.2 Photobolometric Effect (PBE) 12 1.4.5.3 Photothermionic (PTI) Effect 13 1.4.5.4 Photogating Effect 13 1.4.6 Infrared Modulators 16 1.4.7 Photovoltaic Devices 16 1.5 Outlook 17 References 18 2 Growth and Transfer of Graphene for Silicon Optoelectronics 21 2.1 Introduction 21 2.2 Growth of Graphene 21 2.2.1 Growth Dynamics of CVD Gr and Choice of Substrate 22 2.2.2 Growth on Metallic Substrates 24 2.2.3 Direct Growth on Dielectric Substrates 26 2.2.4 Direct Growth on Semiconductor Substrates 29 2.2.5 Large- scale CVD Growth of Graphene 31 2.3 Dielectric Deposition on Graphene 33 2.4 Graphene Transfer Methods 35 vi Contents 2.5 Fabrication of Solution-p rocessed Graphene and Integration with Silicon 38 2.6 Graphene Transfer on Flexible Silicon 39 2.7 Graphene Integration with Silicon in CMOS Process 40 2.8 Challenges and Future Prospectives 41 References 42 3 Physics of Graphene/Silicon Junctions 47 3.1 Introduction 47 3.2 Physics of Schottky Junction 48 3.3 Measurement of Schottky Barrier Height 53 3.3.1 Capacitance Voltage Measurement 53 3.3.2 Current–Voltage Measurement 54 3.3.3 Photoelectric Measurement 55 3.3.4 Thermionic Emission Measurements 55 3.4 2D Materials and Schottky Junctions 58 3.5 Challenges and Future Prospective 61 References 63 4 Graphene/Silicon Junction for High-performance Photodetectors 65 4.1 Introduction 65 4.2 Ultraviolet Photodetectors 65 4.3 Visible to Near-infrared Photodetector 68 4.4 Broadband Photodetectors 71 4.5 Hybrid Gr/Si Photodetectors 75 4.6 Challenges and Perspectives 80 References 81 5 Graphene/Silicon Solar Energy Harvesting Devices 85 5.1 Introduction 85 5.2 Photovoltaic Mechanism and Performance Parameters of Graphene/ Silicon Solar Cells 86 5.3 Theoretical Efficiency Limits of Graphene Silicon Solar Cells 88 5.4 Optimization of Graphene/Silicon Solar Cells 89 5.4.1 Doping of Graphene 89 5.4.2 Light Trapping in Silicon 92 5.4.3 Antireflection Coating 94 5.4.4 Interface Engineering 97 5.4.5 Surface Passivation 100 5.5 Challenges and Perspectives 101 References 102 6 Graphene Silicon- integrated Waveguide Devices 107 6.1 Introduction 107 6.2 Hybrid Waveguide Photodetector 111 6.3 Hybrid Waveguide Modulator 114 6.3.1 Electro- optical Modulator 115 6.3.2 Thermo- optic Modulator 117 Contents vii 6.4 Challenges and Prospectives 117 References 118 7 Graphene for Silicon Image Sensor 121 7.1 Introduction 121 7.2 Quantum Dot- based Infrared Graphene Image Sensor 123 7.3 Graphene Thermopile Image Sensor 124 7.4 Graphene THz Image Sensor 125 7.5 Curved Image Sensor Array 126 7.6 Neural Network Image Sensors 127 7.7 Graphene Charge- coupled Device Image Sensor 128 7.8 Graphene- based Position- sensitive Detector 132 7.9 Challenges and Perspectives 136 References 137 8 System Integration with Graphene for Silicon Optoelectronics 141 8.1 Introduction 141 8.2 Graphene Silicon Flip Chips 142 8.3 Graphene Silicon Heterogeneous Integration 145 8.4 Graphene Silicon Monolithic Integration for Optoelectronics Applications 147 8.5 Challenges and Prospective 150 References 152 9 Graphene for Silicon Optoelectronic Synaptic Devices 153 9.1 Introduction 153 9.2 Silicon Neurons 154 9.3 Synaptic Devices 156 9.4 Silicon Optoelectronic Synaptic Devices 157 9.5 ORAM Synaptic Devices 159 9.6 Graphene for Silicon Synaptic Devices 159 9.7 Synaptic Phototransistor 160 9.8 Broadband, Low-power Optoelectronic Synaptic Devices 163 9.9 Challenges and Prospects 164 References 167 10 Challenges and Prospects of Graphene–Silicon Optoelectronics 169 10.1 Emergence of Wafer‐scale Systems 169 10.2 Wafer‐scale Synthesis and Foundry Process 169 10.3 Scalable Transfer and Quality Metrics 171 10.4 Scaling Laws and Hot‐electron Effects 172 10.5 Optical Modulators 173 10.6 Infrared Photodetectors 174 10.7 Neuromorphic Optoelectronics 176 References 176 Index 177