1 THE 2D SEMICONDUCTOR LIBRARY1.1 Introduction1.2. Emerging 2DLMs for Future Electronics2 THE 2D SEMICONDUCTOR SYNTHESIS AND PERFORMANCES2.1 Exfoliation2.2 Chemical Vapor Deposition3 THE VDW HETEROSTRUCTURE CONTROLLABLE FABRICATIONS3.1 Wet Transfer3.2 Controllable Selective Synthesis3.3 Dry Transfer4 THE MIXED-DIMENSIONAL VDW HETEROSTRUCTURES4.1 Categorization of Mixed-dimensional VdWHs4.2 Strategies for Constructing Mixed-dimensional VdWHs4.3 Electronic and Sensing Applications4.4 Optoelectronic and Photonic Applications4.5 Energy Applications4.6 Conclusions5 THE VDW HETEROSTRUCTURE INTERFACE PHYSICS5.1 Band Alignment and Charge Transfer in VdWHs5.2 Magnetic Coupling in VdWHs5.3 Moiré Pattern5.4 VdWHs for Protection5.5 Characterization Techniques for VdWHs6THE VDW HETEROSTRUCTURE MULTI-FIELD COUPLING EFFECTS6.1 Introduction6.2 The Multi-Field Coupling Effect Characterization for 2D Van der Waals Structures6.3 The Multi-Field Modulation for Electrical Properties of 2D Van der Waals Structures6.4 The Multi-Field Modulation for Optical Properties of 2D Van der Waals Structures7 VDW HETEROSTRUCTURE ELECTRONICS7.1 Van der Waals PN Junctions7.2 Van der Waals Metal-semiconductor Junctions7.3 Field-effect Transistor7.4 Junction Field Effect Transistor7.5 Tunneling Field-effect Transistor7.6 Van der Waals Integration8 VDW HETEROSTRUCTURE OPTOELECTRONICS8.1 Photodetectors8.2 Light Emission8.3 Optical Modulators9 VDW HETEROSTRUCTURE ELECTROCHEMICAL APPLICATIONS9.1 Solar Energy9.2 Van der Waals Heterostructure Application on Hydrogen Energy9.3 Battery9.4 Catalyst9.5 Biotechnology10 PERSPECTIVE AND OUTLOOK10.1 Overall Development Status of 2D Materials10.2 Compatibility between 2D van der Waals device processing and silicon technology10.3. Promising Roadmap of Van der Waals heterostructure devices [Medium term: 5 years, Long term: 5-10 years]10.4 Promising Roadmap of Optoelectronic Device10.5 Conclusion and Prospect
Dr. Yue Zhang is the academician of Chinese academic society and a full professor of material physics at University of Science and Technology Beijing, China. He has committed to make systematic and innovative contributions to low-dimensional semiconductor materials, functional nanodevices, and nanoscale failure and service behaviors. He has authored over 400 scientific publications and has been nominated as the chief scientist of Major National Scientific Research Projects in China. He won the second prize of the national award for natural sciences.Dr. Zheng Zhang currently is associated professor of School of materials science and engineering in the University of Science and Technology Beijing. His research mainly focuses on two-dimensional atomic crystal materials, nanoelectronics and optoelectronic devices and Low dimensional nano material energy converters. He has published more than 100 peer-reviewed articles in international journals with H-index 35.Qingliang Liao received his Ph.D. degree from University of Science and Technology Beijing (USTB) in 2009. Now he is a professor at Academy for Advanced and Interdisciplinary Science and Technology in USTB. His scientific interests focus on synthesis and characterization of low-dimensional nanomaterials, design and application of functional nanodevices. He has published more than 170 papers in high-quality journals, and has been cited more than 6000 times. He applied for more than 60 national invention patents, and has obtained more than 30 authorized patents. He participated in the writing of 2 English monographs, and his research results have been widely recognized by domestic and foreign counterparts. In addition, he also serves as the editorial board member of 4 international academic journals. Zhuo Kang received his B.S. (2011) and Ph.D. degree (2016) from School of Materials Science and Engineering at University of Science and Technology Beijing (USTB). He is currently a full professor of Material Physics at USTB. His research interests include controllable synthesis and interface engineering of nanomaterials as well as their applications in energy conversion and catalysis, specifically focusing on the efficient modulation of service behaviors under multifield coupling condition and lifetime dynamic structure-performance correlations of electrocatalysts under the service environment.