师资
辛涛,南方科技大学副研究员、博导、广东省杰青、深圳量子信息专委会副主任。2017年,提前博士毕业于清华大学物理系(导师龙桂鲁教授),随后作为独立PI加入南方科技大学。2015-2016年曾作为访问学者前往加拿大量子计算研究中心,师从自旋量子计算实验奠基人、加拿大科学院院士Raymond Laflamme教授。长期致力于核自旋量子信息处理研究,经过近十年发展,我们已经形成一支年轻、奋战在科研第一线的研究队伍,并基于核自旋体系做出一系列学术研究成果,同时基于长期技术沉淀,实现了核磁共振量子云计算和小型化的产业化落地,被称‘拉开中国版量子云序幕’。至今共发表SCI论文50多篇,包括9篇Phys.Rev.Lett.,其中一作和通讯Phys.Rev.Lett.6 篇、Sci.Bull.3篇、npj Quant.Inf.3篇及10余篇其他PR系列论文,申请发明专利4项(授权1项),现主持广东省杰出青年项目、国自然面上项目各一项。研究成果被诺贝尔奖、狄拉克奖、尤里卡奖等权威奖项获得者引用,并被Nature Materials、Phys.org 等著名期刊和媒体专文报道。
基本信息
姓名:辛涛
职称:副研究员
邮 箱:xint@sustech.edu.cn
研究方向
1.核自旋量子计算
基于核电共振、核磁共振等核自旋体系的量子信息处理研究。
2.量子测量、层析和表征
量子态保真度、量子纠缠、量子噪声等表征;快速去噪量子态/过程层析;量子体系校验。
3.量子机器学习
机器学习辅助的量子表征;量子神经网络设计和应用;量子增强型机器学习。
教育背景
2013.08-2018.01 博士(量子计算) 清华大学理学院物理系
2015.03-2016.03 访问学者(量子计算) 加拿大滑铁卢大学量子计算研究中心
2009.08-2013.07 学士(核物理学) 哈尔滨工业大学理学院物理系
工作经历
2021.06-至今 南方科技大学量子科学与工程研究 副研究员
2018.04-2021.05 南方科技大学量子科学与工程研究 助理研究员
2018.02-2018.03 南方科技大学物理系 访问学者
代表性论文:
1. Shi-Jie Wei, Chao Wei, Peng Lv, Chang-Peng Shao, Pao Gao, Zengrong Zhou, Keren Li, Tao Xin†, Gui-Lu Long†. A quantum algorithm for heat conduction with symmetrization. Science Bulletin, 68, 494-502 (2023)
2. Xinfang Nie∗, Xuanran Zhu∗, Keyi Huang, Kai Tang, Xinyue Long, Zidong Lin, Yu Tian, Chudan Qiu, Cheng Xi, Xiaodong Yang, Jun Li, Ying Dong†, Tao Xin†, Dawei Lu†. Experimental realization of a quantum refrigerator driven by indefinite causal orders. Physical Review Letters, 129,100603 (2022)
3. Zidong Lin, Lin Zhang, Xinyue Long, Yu-ang Fan, Yishan Li, Kai Tang, Jun Li, XinFang Nie, Tao Xin†, Xiong-Jun Liu†, Dawei Lu†, Experimental quantum simulation of non-Hermitian dynamical topological states using stochastic Schrödinger equation. npj Quantum Information, 8(1), 1-13 (2022)
4. Liangyu Che, Chao Wei, Yulei Huang, Dafa Zhao, Shunzhong Xue, Xinfang Nie, JunLi†, Dawei Lu† and Tao Xin†. Learning Quantum Hamiltonians from Single-qubit Measurements, Physical Review Research, 3,023246 (2021)
5. Tao Xin†, Liangyu Che, Cheng Xi, Amandeep Singh, Xinfang Nie, Jun Li†, Ying Dong†, and Dawei Lu†, Experimental Quantum Principal Component Analysis via Parameterized Quantum Circuits, Physical Review Letters, 126,110502 (2021)
6. Qihao Guo, Yuan-Yuan Zhao, Markus Grassl, Xinfang Nie, Guo-Yong Xiang†, Tao Xin†, et al, Testing a quantum error-correcting code on various platforms. Science Bulletin, 66 (1),29-35 (2021)
7. Tao Xin†, Yishan Li, Yu-ang Fan, Xuanran Zhu, Yingjie Zhang, Xinfang Nie, Jun Li†, Qihang Liu†, and Dawei Lu†, Quantum Phases of Three-Dimensional Chiral Topological Insulators on a Spin Quantum Simulator. Physical Review Letters 125, 090502 (2020)
8. Xinfang Nie∗, Bo-Bo Wei∗, Xi Chen, Ze Zhang, Xiuzhu Zhao, Chudan Qiu, Yu Tian, Yunlan Ji, Tao Xin†, Dawei Lu†, and Jun Li†, Experimental Observation of Equilibrium and Dynamical Quantum Phase Transitions via Out-of-Time-Ordered Correlators, Physical Review Letters 124, 250601 (2020)
9. Wen JingWei, Qin GuoQing, Zheng Chao, Wei ShiJie, Kong XiangYu, Xin Tao†, & Long GuiLu†, Observation of information flow in the anti-PT-symmetric system with nuclear spins. npj Quantum Information, 6(1), 1-7 (2020)
10. Xin Tao†, Nie XinFang, Kong XiangYu, Wen JingWei, et al, Quantum Pure State Tomography via Variational Hybrid Quantum-Classical Method. Physical Review Applied, 13, 024013 (2020)
11. Tao Xin†, Improved Quantum State Tomography for Systems with XX+YY Couplings and Z Readouts. Physical Review A, 102(5),052410 (2020)
12. Xin Tao∗, Lu SiRui∗, Cao NingPing∗, Anikeeva G., et al, Local-measurement-based quantum state tomography via neural networks. npj Quantum Information, 5(1), 1-8 (2019)
13. Tao Xin, Shilin Huang, Sirui Lu, Keren Li, Zhihuang Luo, Zhangqi Yin, et al, NMRCloudQ: A Quantum Cloud Experience on a Nuclear Magnetic Resonance Quantum Computer, Science Bulletin 63(1):17-23 (2018)
14. Tao Xin∗, Dawei Lu∗, Joel Klassen∗, Nengkun Yu, Zhengfeng Ji, Jianxin Chen, Xian Ma, et al, Quantum State Tomography via Reduced Density Matrices, Physical Review Letters 118, 020401 (2017)
15. Dawei Lu∗ ,Tao Xin∗ , Nengkun Yu∗ , Zhengfeng Ji, Jianxin Chen, Guilu Long, Jonathan Baugh, et al, Tomography is Necessary for Universal Entanglement Detection with Single-Copy Observables, Physical Review Letters 116, 230501 (2016)