Two-dimensional materials for future information technology: status and prospects

Hao Qiu; Zhihao Yu; Tiange Zhao; Qi Zhang; Mingsheng Xu; Peifeng Li; Taotao Li; Wenzhong Bao; Yang Chai; Shula Chen; Yiqi Chen; Hui Ming Cheng; Daoxin Dai; Zengfeng Di; Zhuo Dong; Xidong Duan; Yuhan Feng; Yu Fu; Jingshu Guo; Pengwen Guo; Yue Hao; Jun He; Xiao He; Jingyi Hu; Weida Hu; Zehua Hu; Xinyue Huang; Ziyang Huang; Ali Imran; Ziqiang Kong; Jia Li; Qian Li; Weisheng Li; Lei Liao; Bilu Liu; Can Liu; Chunsen Liu; Guanyu Liu; Kaihui Liu; Liwei Liu; Sheng Liu; Yuan Liu; Donglin Lu; Likuan Ma; Feng Miao; Zhenhua Ni; Jing Ning; Anlian Pan; Tian Ling Ren; Haowen Shu; Litao Sun; Yue Sun; Quanyang Tao; Zi Ao Tian; Dong Wang; Hao Wang; Haomin Wang; Jialong Wang; Junyong Wang; Wenhui Wang; Xingjun Wang; Yeliang Wang; Yuwei Wang; Zhenyu Wang; Yao Wen; Haidi Wu; Hongzhao Wu; Jiangbin Wu; Yanqing Wu; Longfei Xia; Baixu Xiang; Luwen Xing; Qihua Xiong; Xiong Xiong; Jeffrey Xu; Tao Xu; Yang Xu; Liu Yang; Yi Yang; Yuekun Yang; Lei Ye; Yu Ye; Bin Yu; Ting Yu; Hui Zeng; Guangyu Zhang; Hongyun Zhang; Jincheng Zhang; Kai Zhang; Tao Zhang; Xinbo Zhang; Yanfeng Zhang; Chunsong Zhao; Yuda Zhao; Ting Zheng; Peng Zhou; Shuyun Zhou; Yuxuan Zhu; Deren Yang; Yi Shi; Han Wang; Xinran Wang

doi:10.1007/s11432-024-4033-8

Two-dimensional materials for future information technology: status and prospects

Hao Qiu
, Zhihao Yu
, Tiange Zhao
, Qi Zhang
, Mingsheng Xu
, Peifeng Li
, Taotao Li
, Wenzhong Bao
, Yang Chai
, Shula Chen
, Yiqi Chen
, Hui Ming Cheng
, Daoxin Dai
, Zengfeng Di
, Zhuo Dong
, Xidong Duan
, Yuhan Feng
, Yu Fu
, Jingshu Guo
, Pengwen Guo

Yue Hao, Jun He, Xiao He, Jingyi Hu, Weida Hu, Zehua Hu, Xinyue Huang, Ziyang Huang, Ali Imran, Ziqiang Kong, Jia Li, Qian Li, Weisheng Li, Lei Liao, Bilu Liu, Can Liu, Chunsen Liu, Guanyu Liu, Kaihui Liu, Liwei Liu, Sheng Liu, Yuan Liu, Donglin Lu, Likuan Ma, Feng Miao, Zhenhua Ni, Jing Ning, Anlian Pan, Tian Ling Ren, Haowen Shu, Litao Sun, Yue Sun, Quanyang Tao, Zi Ao Tian, Dong Wang, Hao Wang, Haomin Wang, Jialong Wang, Junyong Wang, Wenhui Wang, Xingjun Wang, Yeliang Wang, Yuwei Wang, Zhenyu Wang, Yao Wen, Haidi Wu, Hongzhao Wu, Jiangbin Wu, Yanqing Wu, Longfei Xia, Baixu Xiang, Luwen Xing, Qihua Xiong, Xiong Xiong, Jeffrey Xu, Tao Xu, Yang Xu, Liu Yang, Yi Yang, Yuekun Yang, Lei Ye, Yu Ye, Bin Yu, Ting Yu, Hui Zeng, Guangyu Zhang, Hongyun Zhang, Jincheng Zhang, Kai Zhang, Tao Zhang, Xinbo Zhang, Yanfeng Zhang, Chunsong Zhao, Yuda Zhao, Ting Zheng, Peng Zhou, Shuyun Zhou, Yuxuan Zhu, Deren Yang^*, Yi Shi^*, Han Wang^*, Xinran Wang^*

^*Corresponding author for this work

School of Integrated Circuits and Electronics

Nanjing University
Nanjing University of Posts and Telecommunications
CAS - Shanghai Institute of Technical Physics
Southeast University, Nanjing
Zhejiang University
Suzhou Laboratory
Fudan University
Shaoxin Laboratory
Hong Kong Polytechnic University
Hunan University
Tsinghua University
CAS - Shanghai Institute of Microsystem and Information Technology
CAS - Suzhou Institute of Nano-Tech and Nano-Bionics
Renmin University of China
Xidian University
Wuhan University
Huazhong University of Science and Technology
Peking University
Purple Mountain Laboratories
Swiss Federal Institute of Technology Lausanne
CAS - Institute of Semiconductors
Beijing Academy of Quantum Information Sciences
Huawei Technologies Co., Ltd.
CAS - Institute of Physics
Songshan Lake Materials Laboratory
The University of Hong Kong

Research output: Contribution to journal › Review article › peer-review

86 Citations (Scopus)

Abstract

Over the past 70 years, the semiconductor industry has undergone transformative changes, largely driven by the miniaturization of devices and the integration of innovative structures and materials. Two-dimensional (2D) materials like transition metal dichalcogenides (TMDs) and graphene are pivotal in overcoming the limitations of silicon-based technologies, offering innovative approaches in transistor design and functionality, enabling atomic-thin channel transistors and monolithic 3D integration. We review the important progress in the application of 2D materials in future information technology, focusing in particular on microelectronics and optoelectronics. We comprehensively summarize the key advancements across material production, characterization metrology, electronic devices, optoelectronic devices, and heterogeneous integration on silicon. A strategic roadmap and key challenges for the transition of 2D materials from basic research to industrial development are outlined. To facilitate such a transition, key technologies and tools dedicated to 2D materials must be developed to meet industrial standards, and the employment of AI in material growth, characterizations, and circuit design will be essential. It is time for academia to actively engage with industry to drive the next 10 years of 2D material research.

Original language	English
Article number	160400
Journal	Science China Information Sciences
Volume	67
Issue number	6
DOIs	https://doi.org/10.1007/s11432-024-4033-8
Publication status	Published - Jun 2024

Keywords

information technology
microelectronic devices
multi-functional integration
optoelectronic devices
production technology
standardization of characterization
two-dimensional (2D) materials

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10.1007/s11432-024-4033-8

Cite this

Qiu, H., Yu, Z., Zhao, T., Zhang, Q., Xu, M., Li, P., Li, T., Bao, W., Chai, Y., Chen, S., Chen, Y., Cheng, H. M., Dai, D., Di, Z., Dong, Z., Duan, X., Feng, Y., Fu, Y., Guo, J., ... Wang, X. (2024). Two-dimensional materials for future information technology: status and prospects. Science China Information Sciences, 67(6), Article 160400. https://doi.org/10.1007/s11432-024-4033-8

@article{68d32cc0627b4d5fb76ab98c4cfc0936,

title = "Two-dimensional materials for future information technology: status and prospects",

abstract = "Over the past 70 years, the semiconductor industry has undergone transformative changes, largely driven by the miniaturization of devices and the integration of innovative structures and materials. Two-dimensional (2D) materials like transition metal dichalcogenides (TMDs) and graphene are pivotal in overcoming the limitations of silicon-based technologies, offering innovative approaches in transistor design and functionality, enabling atomic-thin channel transistors and monolithic 3D integration. We review the important progress in the application of 2D materials in future information technology, focusing in particular on microelectronics and optoelectronics. We comprehensively summarize the key advancements across material production, characterization metrology, electronic devices, optoelectronic devices, and heterogeneous integration on silicon. A strategic roadmap and key challenges for the transition of 2D materials from basic research to industrial development are outlined. To facilitate such a transition, key technologies and tools dedicated to 2D materials must be developed to meet industrial standards, and the employment of AI in material growth, characterizations, and circuit design will be essential. It is time for academia to actively engage with industry to drive the next 10 years of 2D material research.",

keywords = "information technology, microelectronic devices, multi-functional integration, optoelectronic devices, production technology, standardization of characterization, two-dimensional (2D) materials",

author = "Hao Qiu and Zhihao Yu and Tiange Zhao and Qi Zhang and Mingsheng Xu and Peifeng Li and Taotao Li and Wenzhong Bao and Yang Chai and Shula Chen and Yiqi Chen and Cheng, \{Hui Ming\} and Daoxin Dai and Zengfeng Di and Zhuo Dong and Xidong Duan and Yuhan Feng and Yu Fu and Jingshu Guo and Pengwen Guo and Yue Hao and Jun He and Xiao He and Jingyi Hu and Weida Hu and Zehua Hu and Xinyue Huang and Ziyang Huang and Ali Imran and Ziqiang Kong and Jia Li and Qian Li and Weisheng Li and Lei Liao and Bilu Liu and Can Liu and Chunsen Liu and Guanyu Liu and Kaihui Liu and Liwei Liu and Sheng Liu and Yuan Liu and Donglin Lu and Likuan Ma and Feng Miao and Zhenhua Ni and Jing Ning and Anlian Pan and Ren, \{Tian Ling\} and Haowen Shu and Litao Sun and Yue Sun and Quanyang Tao and Tian, \{Zi Ao\} and Dong Wang and Hao Wang and Haomin Wang and Jialong Wang and Junyong Wang and Wenhui Wang and Xingjun Wang and Yeliang Wang and Yuwei Wang and Zhenyu Wang and Yao Wen and Haidi Wu and Hongzhao Wu and Jiangbin Wu and Yanqing Wu and Longfei Xia and Baixu Xiang and Luwen Xing and Qihua Xiong and Xiong Xiong and Jeffrey Xu and Tao Xu and Yang Xu and Liu Yang and Yi Yang and Yuekun Yang and Lei Ye and Yu Ye and Bin Yu and Ting Yu and Hui Zeng and Guangyu Zhang and Hongyun Zhang and Jincheng Zhang and Kai Zhang and Tao Zhang and Xinbo Zhang and Yanfeng Zhang and Chunsong Zhao and Yuda Zhao and Ting Zheng and Peng Zhou and Shuyun Zhou and Yuxuan Zhu and Deren Yang and Yi Shi and Han Wang and Xinran Wang",

note = "Publisher Copyright: {\textcopyright} The Author 2024.",

year = "2024",

month = jun,

doi = "10.1007/s11432-024-4033-8",

language = "English",

volume = "67",

journal = "Science China Information Sciences",

issn = "1674-733X",

publisher = "Science China Press",

number = "6",

}

Qiu, H, Yu, Z, Zhao, T, Zhang, Q, Xu, M, Li, P, Li, T, Bao, W, Chai, Y, Chen, S, Chen, Y, Cheng, HM, Dai, D, Di, Z, Dong, Z, Duan, X, Feng, Y, Fu, Y, Guo, J, Guo, P, Hao, Y, He, J, He, X, Hu, J, Hu, W, Hu, Z, Huang, X, Huang, Z, Imran, A, Kong, Z, Li, J, Li, Q, Li, W, Liao, L, Liu, B, Liu, C, Liu, C, Liu, G, Liu, K, Liu, L, Liu, S, Liu, Y, Lu, D, Ma, L, Miao, F, Ni, Z, Ning, J, Pan, A, Ren, TL, Shu, H, Sun, L, Sun, Y, Tao, Q, Tian, ZA, Wang, D, Wang, H, Wang, H, Wang, J, Wang, J, Wang, W, Wang, X, Wang, Y, Wang, Y, Wang, Z, Wen, Y, Wu, H, Wu, H, Wu, J, Wu, Y, Xia, L, Xiang, B, Xing, L, Xiong, Q, Xiong, X, Xu, J, Xu, T, Xu, Y, Yang, L, Yang, Y, Yang, Y, Ye, L, Ye, Y, Yu, B, Yu, T, Zeng, H, Zhang, G, Zhang, H, Zhang, J, Zhang, K, Zhang, T, Zhang, X, Zhang, Y, Zhao, C, Zhao, Y, Zheng, T, Zhou, P, Zhou, S, Zhu, Y, Yang, D, Shi, Y, Wang, H & Wang, X 2024, 'Two-dimensional materials for future information technology: status and prospects', Science China Information Sciences, vol. 67, no. 6, 160400. https://doi.org/10.1007/s11432-024-4033-8

TY - JOUR

T1 - Two-dimensional materials for future information technology

T2 - status and prospects

AU - Qiu, Hao

AU - Yu, Zhihao

AU - Zhao, Tiange

AU - Zhang, Qi

AU - Xu, Mingsheng

AU - Li, Peifeng

AU - Li, Taotao

AU - Bao, Wenzhong

AU - Chai, Yang

AU - Chen, Shula

AU - Chen, Yiqi

AU - Cheng, Hui Ming

AU - Dai, Daoxin

AU - Di, Zengfeng

AU - Dong, Zhuo

AU - Duan, Xidong

AU - Feng, Yuhan

AU - Fu, Yu

AU - Guo, Jingshu

AU - Guo, Pengwen

AU - Hao, Yue

AU - He, Jun

AU - He, Xiao

AU - Hu, Jingyi

AU - Hu, Weida

AU - Hu, Zehua

AU - Huang, Xinyue

AU - Huang, Ziyang

AU - Imran, Ali

AU - Kong, Ziqiang

AU - Li, Jia

AU - Li, Qian

AU - Li, Weisheng

AU - Liao, Lei

AU - Liu, Bilu

AU - Liu, Can

AU - Liu, Chunsen

AU - Liu, Guanyu

AU - Liu, Kaihui

AU - Liu, Liwei

AU - Liu, Sheng

AU - Liu, Yuan

AU - Lu, Donglin

AU - Ma, Likuan

AU - Miao, Feng

AU - Ni, Zhenhua

AU - Ning, Jing

AU - Pan, Anlian

AU - Ren, Tian Ling

AU - Shu, Haowen

AU - Sun, Litao

AU - Sun, Yue

AU - Tao, Quanyang

AU - Tian, Zi Ao

AU - Wang, Dong

AU - Wang, Hao

AU - Wang, Haomin

AU - Wang, Jialong

AU - Wang, Junyong

AU - Wang, Wenhui

AU - Wang, Xingjun

AU - Wang, Yeliang

AU - Wang, Yuwei

AU - Wang, Zhenyu

AU - Wen, Yao

AU - Wu, Haidi

AU - Wu, Hongzhao

AU - Wu, Jiangbin

AU - Wu, Yanqing

AU - Xia, Longfei

AU - Xiang, Baixu

AU - Xing, Luwen

AU - Xiong, Qihua

AU - Xiong, Xiong

AU - Xu, Jeffrey

AU - Xu, Tao

AU - Xu, Yang

AU - Yang, Liu

AU - Yang, Yi

AU - Yang, Yuekun

AU - Ye, Lei

AU - Ye, Yu

AU - Yu, Bin

AU - Yu, Ting

AU - Zeng, Hui

AU - Zhang, Guangyu

AU - Zhang, Hongyun

AU - Zhang, Jincheng

AU - Zhang, Kai

AU - Zhang, Tao

AU - Zhang, Xinbo

AU - Zhang, Yanfeng

AU - Zhao, Chunsong

AU - Zhao, Yuda

AU - Zheng, Ting

AU - Zhou, Peng

AU - Zhou, Shuyun

AU - Zhu, Yuxuan

AU - Yang, Deren

AU - Shi, Yi

AU - Wang, Han

AU - Wang, Xinran

PY - 2024/6

Y1 - 2024/6

N2 - Over the past 70 years, the semiconductor industry has undergone transformative changes, largely driven by the miniaturization of devices and the integration of innovative structures and materials. Two-dimensional (2D) materials like transition metal dichalcogenides (TMDs) and graphene are pivotal in overcoming the limitations of silicon-based technologies, offering innovative approaches in transistor design and functionality, enabling atomic-thin channel transistors and monolithic 3D integration. We review the important progress in the application of 2D materials in future information technology, focusing in particular on microelectronics and optoelectronics. We comprehensively summarize the key advancements across material production, characterization metrology, electronic devices, optoelectronic devices, and heterogeneous integration on silicon. A strategic roadmap and key challenges for the transition of 2D materials from basic research to industrial development are outlined. To facilitate such a transition, key technologies and tools dedicated to 2D materials must be developed to meet industrial standards, and the employment of AI in material growth, characterizations, and circuit design will be essential. It is time for academia to actively engage with industry to drive the next 10 years of 2D material research.

AB - Over the past 70 years, the semiconductor industry has undergone transformative changes, largely driven by the miniaturization of devices and the integration of innovative structures and materials. Two-dimensional (2D) materials like transition metal dichalcogenides (TMDs) and graphene are pivotal in overcoming the limitations of silicon-based technologies, offering innovative approaches in transistor design and functionality, enabling atomic-thin channel transistors and monolithic 3D integration. We review the important progress in the application of 2D materials in future information technology, focusing in particular on microelectronics and optoelectronics. We comprehensively summarize the key advancements across material production, characterization metrology, electronic devices, optoelectronic devices, and heterogeneous integration on silicon. A strategic roadmap and key challenges for the transition of 2D materials from basic research to industrial development are outlined. To facilitate such a transition, key technologies and tools dedicated to 2D materials must be developed to meet industrial standards, and the employment of AI in material growth, characterizations, and circuit design will be essential. It is time for academia to actively engage with industry to drive the next 10 years of 2D material research.

KW - information technology

KW - microelectronic devices

KW - multi-functional integration

KW - optoelectronic devices

KW - production technology

KW - standardization of characterization

KW - two-dimensional (2D) materials

UR - https://www.scopus.com/pages/publications/85195384425

U2 - 10.1007/s11432-024-4033-8

DO - 10.1007/s11432-024-4033-8

M3 - Review article

AN - SCOPUS:85195384425

SN - 1674-733X

VL - 67

JO - Science China Information Sciences

JF - Science China Information Sciences

IS - 6

M1 - 160400

ER -

Two-dimensional materials for future information technology: status and prospects

Abstract

Keywords

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