基本信息

童昕    男    精密测量科学与技术创新研究院
电子邮件:   tongxin@wipm.ac.cn
通信地址:   中国科学院武汉物理与数学所,武汉武昌小洪山西30号
邮政编码:    430071
研究组网页:http://cami.apm.ac.cn/


研究领域

²  长期致力于囚禁离子体系的精密测量物理研究,在Nature PhysicsPhysical Review Letters 等国际期刊发表论文 50 余篇,获授权发明专利 8 项。担任简单原子体系精密测量”“精密测量物理与基本物理常数”“可控冷分子离子等国际会议咨询委员。主持科技部国家物态调控重点研发计划课题、国家自然科学基金委少电子原子分子精密谱重大项目课题、精密测量物理重大科学研究计划重点项目,以及中国科学院基于原子的精密测量物理战略性科技先导专项项目等多项研究计划。

² 研究内容详见:http://cami.apm.ac.cn/research

招生信息

The CAMI (Cold Atomic and Molecular Ions @ http://cami.apm.ac.cn/ ) Group is on the hunt for highly motivated individuals to join our dynamic research team. Whether you are interested in an undergraduate internship, pursuing a master's or Ph.D. degree, taking up a postdoctoral position, or participating in our research projects, we'd love to hear from you. Please contact Prof Xin Tong at tongxin@wipm.ac.cn.


招生专业
070203-原子与分子物理
070304-物理化学(含:化学物理)
招生方向
原子分子物理,精密测量物理,
超冷分子离子,分子激光光谱,分子反应动力学
激光光谱,物理化学,超冷体系物理化学

教育背景

2000-10--2005-08   英国约克(York)大学   博士
1995-09--2000-07   中国科技大学   学士

工作经历

2005-2008 英国曼彻斯特大学(The University of Manchester),光子科学所,助理研究员;

2008-2012 瑞士巴塞尔大学(University of Basel),物理化学所,高级助理研究员


教授课程

分子反应动力学、 分子光谱、 量子化学、 物理化学

论文

2025:

  • Bai, W. et al. Frequency stabilization of multiple continuous-wave lasers via a precision wavelength meter. Opt. Laser Technol. 189, 113076 (2025).

  • XU,Huaxuan et al. Performance of radio frequency source based on electronic tube oscillation circuit for ion traps. CHINESE J. QUANTUM Electron. 42, 229 (2025).

  • Tong, X., Linqiang, H., Hua, X. & Liu, X. The Ticking of Thorium Nuclear Optical Clocks: A Developmental Perspective. Natl. Sci. Rev. 12, nwaf083 (2025).

  • Zhang, Q.-Y et al. Two-photon dissociation of BeH + with a middle ultraviolet band laser. Chinese Phys. B 34, 033301 (2025).

2024:

  • Zhang, Q.-Y. et al. Precision measurement based on rovibrational spectrum of cold molecular hydrogen ion. Acta Phys. Sin. 73, 203301 (2024).

  • Yu, S., Gan, W., Hua, X., Tong, X. & Li, C. 229Th3+ as an ionic optical clock for fine-structure-constant variations. Phys. Rev. A 109, 063115 (2024).

  • Tong, X. Precisely simple. Nat. Phys. 20, 346–347 (2024).

  • Bai, W. L. et al. Long term frequency stabilization and frequency drift suppression of the 313 nm laser. Chinese J. Phys. 89, 1500–1507 (2024).

  • Li, Z., Li, L., Hua, X. & Tong, X. Loading and identifying various charged thorium ions in a linear ion trap with a time-of-flight mass spectrometer. J. Appl. Phys. 135, 144402 (2024).

  • Li, L., Li, Z., Hua, X. & Tong, X. Dynamic laser ablation loading of a linear Paul trap. J. Phys. D. Appl. Phys. 57, 315205 (2024).

2023:

  • Zhang, Y. et al. An efficient preparation of HD+ molecular ions in an ion trap by REMPI. Chinese J. Phys. 84, 164–172 (2023).

  • Zhang, Y. et al. Generation of rotational-ground-state HD+ ions in an ion trap using a resonance-enhanced threshold photoionization process. Phys. Rev. A 107, 1–8 (2023).

  • Li, M. et al. Investigation of spatial structure and sympathetic cooling in the 9Be+-40Ca+ bi-component Coulomb crystals. Chinese Phys. B 32, 036402 (2023).

  • Li, L. et al. Scheme for the excitation of thorium-229 nuclei based on electronic bridge excitation. Nucl. Sci. Tech. 34, 24 (2023).