张昕，男，博士，研究员，博士生导师。

2010年本科毕业于苏州大学物理系，2015年在中国科学院半导体研究所获得博士学位，师从谭平恒研究员和郑厚植院士；2016年至2020年先后在法国国家科学研究中心（CNRS）、南洋理工大学、康考迪亚大学从事博士后研究。2020年12月通过中国科学院半导体研究所“卓越青年学者”引进人才计划加入半导体所，并获得半导体所青年人才推进计划资助。2022年入选中国科学院高层次人才引进计划。

长期从事新型MEMS/NEMS在量子测量与传感方面的实验研究，取得一系列原创性成果，发表SCI文章40余篇，包括Nature Communications (3篇), Physical Review X (1篇), Chemical Society Reviews (1篇)，ACS Nano (3篇)，Carbon (4篇), Physical Review B (4篇)，Applied Physics Letters (1篇)，Chinese Physics Letters（2篇）等，总引超7000次，著有译著《量子光力学》。

主要研究领域方向：

1.新型MEMS/NEMS

2.量子测量与传感

3.混合量子系统

4.极端条件显微光谱学

取得的重要科研成果及所获奖励：

(1) 实现基于转角石墨烯的纳机电谐振器，揭示出由层间滑移诱导的黏弹性，证实黏弹性效应通过类似耗散稀释的方式显著地提升了机械谐振器的品质因子。该研究开启了“莫尔超晶格纳米机械谐振器”（Moiré NEMS）这一全新研究方向，为表界面动力学的研究和精准调控提供了全新思路，更为设计新型高性能NEMS谐振器开辟独特的技术路线。[Nature Communications 16, 3793 (2025)]

(2) 揭示出单层石墨烯机械振子由非线性机械振动增强的动态应变，实现局域声学声子对光学声子的调控，开启动态应变的相关研究。该工作被CNRS、巴黎高师的LKB实验室、斯特拉斯堡大学等宣传报道。[Nature Communications 11, 5526 (2020); Chinese Physics Letters 43, 050701 (2026).]

(3) 建立二维层状体系层间声子的普适模型，将其应用于少层体系层数的精确表征以及转角体系；基于单光栅光谱仪开发出超低波数拉曼光谱技术，可与各种极端条件进行联用。[Physical Review B 87, 115413 (2013); Nature Communications 5, 5309 (2014); Chemical Society Reviews 44, 2757-2785 (2015)]

国科大主讲课程：

研究生：《量子光机电系统研究进展》（夏季学期，雁栖湖校区）

在研/完成项目：

1.国家自然科学基金委重大研究计划，2026-2028，主持

2.国家自然科学基金委面上项目，2022-2025，主持

3.中国科学院先导专项，2025-2030，骨干

4.北京市自然科学基金重点研究专题项目，2022-2026，骨干

5.中国科学院基础研究领域优秀青年团队项目，2021-2025，骨干

联系方式：

E-mail: zhangxin@semi.ac.cn

代表性论文或著作（*为通讯作者）：

张昕，马稳龙，邓光伟《量子光力学》[译著]（2024），中国科学技术大学出版社.

1. Qin-Yang Zeng, Gui-Xin Su, Xin-Yu Mei, Han Wang, Ping-Heng Tan* and Xin Zhang*, Nano-opto-electro-mechanical systems from moiré superlattices, Chinese Physics Letters 43, 050701 (2026).

2. Wen-Jun Wang, Ping-Heng Tan*, Xin Zhang*, Supermoiré domains in helical trilayer graphene (NEWS AND VIEWS), Journal of Semiconductors (2026). Doi: 10.1088/1674-4926/26030014

3. Qin-Yang Zeng, Gui-Xin Su, Ai-Sheng Song, Xin-Yu Mei, Zhi-Yue Xu, Yue Ying, Zhuo-Zhi Zhang, Xiang-Xiang Song, Guang-Wei Deng, Joel Moser*, Tian-Bao Ma, Ping-Heng Tan*, Xin Zhang*, High-quality-factor viscoelastic nanomechanical resonators from moiré superlattices, Nature Communications 16, 3793 (2025).

4. Loïc Moczko, Sven Reichardt, Aditya Singh, Xin Zhang, Elise Jouaiti, Luis E. Parra López, Joanna L. P. Wolff, Aditi Raman Moghe, Etienne Lorchat, Rajendra Singh, Kenji Watanabe, Takashi Taniguchi, Hicham Majjad, Michelangelo Romeo, Arnaud Gloppe, Ludger Wirtz, and Stephane Berciaud*, Symmetry-Dependent Dielectric Screening of Optical Phonons in Monolayer Graphene, Physical Review X 15, 021043 (2025).

5. Yang, Haitao; Hu, Ruiqi; Wu, Heng; He, Xiaolong; Zhou, Yan*; Xue, Yizhe; He, Kexin; Hu, Wenshuai; Chen, Haosen; Gong, Mingming; Zhang, Xin; Tan, Ping-Heng*; Hernandez, Eduardo R.*; Xie, Yong*, Identification and Structural Characterization of Twisted Atomically Thin Bilayer Materials by Deep Learning. Nano Letters 24, 2789-2797, (2024).  

6. Xin Zhang* and Ping-Heng Tan*, Raman spectroscopy: Nanostructures, Encyclopedia of Condensed Matter Physics (Second Edition) 4, 160-172, (2024).  

7. X. Chen, S. Reichardt, M. L. Lin, Y. C. Leng, Y. Lu, H. Wu, R. Mei, L. Wirtz*, X. Zhang*, A. C. Ferrari and P. H. Tan*, Control of Raman scattering quantum interference pathways in graphene, ACS Nano, 17(06), 5956−5962 (2023).

8. Heng Wu, Miao-Ling Lin, Yan Zhou, Xin Zhang, and Ping-Heng Tan*, Analyzing fundamental properties of Two-Dimensional Materials by Raman spectroscopy from Microscale to Nanoscale, Analytical Chemistry 95, 10821-10838, (2023). 

9. Miao-Ling Lin, Min Feng, Jiang-Bin Wu, Fei-Rong Ran, Tao Chen, Wei-Xia Luo, Heng Wu, Wen-Peng Han, Xin Zhang, Xue-Lu Liu, Yang Xu, Hai Li, Yu-Fang Wang, and Ping-Heng Tan*, Research 2022, 9819373, (2022).

10. X. Zhang*, K. Makles, L. Colombier, D. Metten, H. Majjad, P. Verlot & S. Berciaud*, Dynamically-enhanced strain in atomically thin resonators, Nature Communications 11, 5526 (2020).

11. X. Cong, Q. Q. Li, X. Zhang, M. L. Lin, J. B. Wu, X. L. Liu, P. Venezuela & P. H. Tan*, Probing the acoustic phonon dispersion and sound velocity of graphene by Raman spectroscopy, Carbon, 149, 19-24 (2019).

12. M. L. Lin, Q. H. Tan, J. B. Wu, X. S. Chen, J. H. Wang, Y. H. Pan, X. Zhang, X. Cong, J. Zhang, W. Ji, P. A. Hu, K. H. Liu & P. H. Tan*, Moire Phonons in Twisted Bilayer MoS₂, ACS Nano 12(8), 8770-8780(2018).

13. X. Zhang*, Q. H. Tan, J. B. Wu, W. Shi & P. H. Tan*, Review on the Raman spectroscopy of different types of layered materials, Nanoscale, 8, 6435-6450 (2016). 

14. X. Zhang*, W. P. Han, X. F. Qiao, Q. H. Tan, Y. F. Wang, J. Zhang & P. H. Tan, Raman characterization of AB- and ABC-stacked few-layer graphene by interlayer shear modes, Carbon, 99, 18-122(2016).

15. X. Zhang, X. F. Qiao, W. Shi, J. B. Wu, D. S. Jiang & P. H. Tan*, Phonon and Raman scattering of two-dimensional transition metal dichalcogenides from monolayer, multilayer to bulk material, Chemical Society Reviews 44, 2757-2785 (2015).

16. J. B. Wu, Z. X. Hu, X. Zhang, W. P. Han, Y. Lu, W. Shi, X. F. Qiao, M. Ijas, S. Milana, W. Ji*, A. C. Ferrari & P. H. Tan*, Interface Coupling in Twisted Multilayer Graphene by Resonant Raman Spectroscopy of Layer Breathing Modes, ACS Nano 9(7), 7440-7449(2015).

17. X. Zhang, Q. Q. Li, W. P. Han, Y. Lu, W. Shi, J. B. Wu, A. S. Mikhaylushkina & P. H. Tan*, Raman identification of edge alignment of bilayer graphene down to the nanometer scale, Nanoscale, 6(13), 7519-7525(2014).

18. J. B. Wu, X. Zhang, M. Ijas, W. P. Han, X. F. Qiao, X. L. Li, D. S. Jiang, A.C. Ferrari & P. H. Tan*, Resonant Raman spectroscopy of twisted multilayer graphene, Nature Communications 5, 5309(2014).

19. X. Zhang, W. P. Han, J. B. Wu, S. Milana, Y. Lu, Q. Q. Li, A. C. Ferrari* & P. H. Tan*, Raman spectroscopy of shear and layer breathing modes in multilayer MoS2, Physical Review B 87, 115413 (2013).