Dapeng YuChair Professor Dean of IQSE
email: yudp@sustech.edu.cn
Office：room502-12，Taizhou Hall
Research Field：Low dimensional quantum materials, Quantum control, Micro-nano machining







Da-peng Yu
Chair Professor
Southern University of Science andTechnology
Dean
Institutefor Quantum Science and Engineering
E-mail: yudp@sustech.edu.cn
Tel:



Education:
1989-1993:PhD
Laboratoire de Physique des Solides, Université de Paris-Sud, Orsay, France(Materials Physics)
1982-1985: Master
Shanghai Institute of Ceramics, Chinese Acamedy ofSciences
(Inorganic Non-metallic Materials Engineering)
1978-1982: Bachelor
East China University of Science and Technology
(Inorganic Non-metallic Materials Engineering)
Positions:
May 2016–Now
Chair Professor, Physics Department

Southern University of Science and Technology, China

Dean

Institute for Quantum Science and Engineering, China


Sep 1999–May 2016
Professor(Full), School of Physics


Peking University, China


Sep 1995–Sep 1999
Associate Professor, School of Physics

Peking University, China


Nov 1993–Sep 1995
Postdoctoral researcher

Laboratory of Advanced Materials and Electron Microscopy, Institute of Physics, Chinese Academy of Sciences

Honors and Awards (Selected):
2015
Academician of the Chinese Academy of Sciences

2007
National Natural Science Award (second class)


Research Field：
Low dimensional quantum materials, Quantum control, Micro-nanomachining
Biography:
After his PhD in LPS, Orsay, French, Dapeng Yu did hispostdoc in Chinese Academy of Sciences between 1993-1995. From September 1995,he joined department of physics, Peking University as an associate Professor.He was promoted to full professor in 1999 in Peking University. He was electedas a member (Academian) of Chinese Academy of Sciences in 2015.

From June, 2016, he moved to Southern University ofScience and Technology, Shenzhen, and there he set-up the Shenzhen Institutefor Quantum Science and Engineering, which is focusing on fundamentals of theemerging quantum materials, quantum information.

Prof D. P. Yu is one of the world pioneers indeveloping method to synthesize from the bottom, and to characterize1-dimensional semiconductor nanowires and 2-D Dirac quantum Materials, and madeimportant contributions to the investigations of low-dimensional quantummaterials. Resulting from his pioneer contributions, more than 500peer-reviewed work has been published in Physical Journals, including a majorityin APS(33 PRL/PRB papers) and AIP journals (96 papers) and other generalinterest Journals such as NPG (12 papers in Nature and Nature babies) journals;the originality and impact of the nominee’s work is also manifested with acitation of more than 2,9000 times by colleagues world-wide with an H-index of82 (a Google H-index of 92).

He has mentored/trained more than 100 graduates andpostdoctoral associates.
RecentFeatured English Papers：
1. Generation of Single-crystal Copper Sheet withArbitrary Orientation via 1 Seeded Abnormal Grain Growth, Nature , inpress, 2020.
2. Electric control of Fermi arc spin transport inindividual topological semimetal nanowires: Physical Review Letters 124,116802, 2020.
3. Chiral Spin-Wave Velocities Induced by All-GarnetInterfacial Dzyaloshinskii-Moriya Interaction in Ultrathin Yttrium Iron GarnetFilms: PhysicalReview Letters 124,027203, 2020.
4. Simulation of a topological phase transition in aKitaev chain with long-range coupling using a superconducting circuit: Physical Review B 101,035109,2020.
5. Quantum oscillations of thermopower in WTe2 thinfilms: Physical Review B 100,235405, 2019.
6. Experimental Realization of Nonadiabatic Shortcutto Non-Abelian Geometric Gates: Physical Review Letters 122(8), 080501, 2019.
7. Subunit cell-level measurement of polarization inan individual polar vortex: Science Advances 5,4355, 2019.
8. Epitaxial growth of a 100-square-centimetresingle-crystal hexagonal boron nitride monolayer on copper, Wang, Li; Xu,Xiaozhi; Zhang, Leining; Qiao, Ruixi; Wu Muhong;; et al., Nature, 570:91–95，2019.
9. Current-controlled propagation of spin waves inantiparallel, coupled domains; Liu, Chuanpu; Wu, Shizhe; Zhang, Jianyu; Chen,Jilei; et al., Nature nanotechnology, 14:691–697, 2019.
10. Universal Imaging of Full Strain Tensor in 2DCrystals with Third-Harmonic Generation, Liang, Jing; Wang, Jinhuan; Zhang,Zhihong; Su, Yingze; et al., ADVANCED MATERIALS, 31(19): **, 2019.
11. Kinetic modulation of graphene growth by fluorinethrough spatially confined decomposition of metal fluorides, Liu, Can; Xu,Xiaozhi; Qiu, Lu; Wu, Muhong; et al., NATURE CHEMISTRY, 11:730–736 , 2019.
12. Probing Far-Infrared Surface Phonon Polaritons inSemiconductor Nanostructures at Nanoscale, Qi, Ruishi; Wang, Renfei; Li,Yuehui; Sun, Yuanwei; et al., NANO LETTERS, 19(8):5070-5076, 2019.
13. Observation of an Odd-Integer Quantum Hall Effectfrom Topological Surface States in Cd3As2, Lin, Ben-Chuan; Wang, Shuo;Wiedmann, Steffen; et al., PHYSICAL REVIEW LETTERS, 122(3): 036602, 2019.
14. Dirac Semimetal Heterostructures: 3D Cd3As2 on 2DGraphene，Wu, Yan-Fei; Zhang, Liang; Li, Cai-Zhen et al., ADVANCED MATERIALS30(34): **, 2018.
15. Ultrafast Broadband Charge Collectionfrom Clean Graphene/CH(3)NH(3)Pbl(3) Interface, Hong, Hao; Zhang, Jincan;Zhang, Jin; Qiao, Ruixi; et al., Journal of the American Chemical Society,140(44):14952-14957, 2018
16. Differential Enzyme Flexibility ProbedUsing Solid-State Nanopores, Hu, Rui; Rodrigues, Joao V.; Waduge, Pradeep;Yamazaki, Hirohito; et al., ACS NANO, 12(5): 4494-4502, 2018.
17. Long-distance propagation ofshort-wavelength spin waves, Liu, Chuanpu; Chen, Jilei; Liu, Tao; Heimbach,Florian; et al., Nature Communications, 9:738, 2018.
18. Greatly Enhanced Anticorrosion of Cu byCommensurate Graphene Coating,Xu, Xiaozhi; Yi, Ding; Wang, Zhichang et al.ADVANCED MATERIALS 30(6 )**,2018
19. Experimentally probing topologicalorder and its breakdown through modular matrices, Luo, ZH (Luo, Zhihuang); Li,J (Li, Jun); Li, ZK (Li, Zhaokai); et al., Nature Physics,14:160, 2018.
20. Quantum transport in Dirac and Weylsemimetals: a review, Wang, Shuo; Lin, Ben-Chuan; Wang, An-Qi ;Yu, Da-Peng; etal., ADVANCES IN PHYSICS-X, 2(3): 518-544, 2017.
21. Electronic Coupling between Grapheneand Topological Insulator Induced Anomalous Magnetotransport Properties, Zhang,Liang; Lin, Ben-Chuan; Wu, Yan-Fei; et al., ACS Nano,1 1(6): 6277-6285, 2017.
22. Ab initio thermodynamic study ontwo-dimensional atomic nucleation on ZnO polar surfaces, Zhu, Rui; Zhao, Qing;Xu, Jun; Liu, Banggui; et al., Applied Surface Science, 412: 417-423, 2017.
23. Monitoring Local Strain Vector in Atomic-LayeredMoSe2 by Second-Harmonic Generation,Liang, Jing; Zhang, Jin; Li, Zhenzhu; etal., NANO LETTERS 17(12)7539-7543, 2017.
24. Ultrafast epitaxial growth ofmetre-sized single-crystal graphene on industrial Cu foil, Xu, Xiaozhi; Zhang,Zhihong; Dong, Jichen et al., Science Bulletin 62(15): 1074-1080, 2017.
25. Possible absence of critical thicknessand size effect in ultrathin perovskite ferroelectric films, Gao, Peng; Zhang,Zhangyuan; Li, Mingqiang; et al., Nature Communications 8: 15549,2017.
26. Electrical transport in nanothick ZrTe5sheets: From three to two dimensions, Niu, Jingjing; Wang, Jingyue; He, Zhijie;et al., Physical Review B 95: 035420, 2017.
27. Ultrafast growth of single-crystalgraphene assisted by a continuous oxygen supply, Xiaozhi Xu , Zhihong Zhang ,Kaihui Liu; et al., Nature Nanotechnology,11(11): 930-935, 2016.
28. Strain-Gradient Modulated ExcitonEmission in Bent ZnO Wires Probed by Cathodoluminescence, Fu, Xue-Wen; Li,Cai-Zhen; Fang, Liang; et al., ACS Nano, 10(12): 11469-11474, 2016.
29. Aharonov-Bohm oscillations in Diracsemimetal Cd3As2 nanowires, Wang, Li-Xian; Li, Cai-Zhen; Yu, Da-Peng et al., Nature Communications 7: 10769，2016 .
30. A polymer scaffold for self-healingperovskite solar cells, Zhao, Yicheng; Wei, Jing; Li, Heng . et al., Nature Communications 7:10228, 2016
31. Giant negative magnetoresistanceinduced by the chiral anomaly in individual Cd3As2 nanowires, Li, Cai-Zhen;Wang, Li-Xian; Liu, Haiwen et al., Nature Communications 6:10137, 2015
32. Vibrational spectroscopy atelectrolyte/electrode interfaces with graphene gratings, Bie, Ya-Qing; Horng,Jason; Shi, Zhiwen et al., Nature Communications 6:7593,2015
33. Layer-by-layer assembly of verticallyconducting graphene devices, Chen, Jing-Jing; Meng, Jie; Zhou, Yang-Bo; et al., Nature Communications 4:1921, 2013.
34. (2) TunableBandgap in Silicene and Germanene: Nano Letters 12(1), 113-118, 2012.
35. Evidence for Thermal Spin-TransferTorque, Yu, Haiming; Granville, S.; Yu, D. P.; et al., Physical Review Letters 104: 146601, 2010.
36. Optical properties of the ZnO nanotubessynthesized via vapor phase growth: Applied Physics Letters 83(9), 1689-1691, 2003.
37. Ultraviolet-emitting ZnO nanowiressynthesized by a physical vapor deposition approach: Applied Physics Letters 78(4), 407-409, 2001.
38. Amorphous silica nanowires: Intensiveblue light emitters: Applied Physics Letters 73(21), 3076-3078, 1998.