Optical atomic clocks

2004-09--2009-07   Doctor of Science (Radio Physics), Peking University, CHINA

2000-09--2004-07   Bachelor of Engineering (Electronic Science and Technology), Shandong University, CHINA

1. 06. 2022 – , Professor, National Time Service Center, Xi’an, Shannxi, China

2. 07. 2019 – 06. 2022, Research Fellow, University of Exeter, UK

3. 07. 2015 – 08. 2018, Research Fellow, Centre for Quantum Technologies, National University of Singapore, Singapore

4. 01. 2013 – 10. 2014, Research Fellow, University of Nottingham, UK

5. 11. 2009 – 12. 2012, JSPS Postdoctoral Fellow, University of Tokyo, Japan

Book 

Optical Whispering Gallery Modes for Biosensing: From Physical Principles to Applications. F. Vollmer and Deshui Yu, Springer International Publishing, 2020.

Articles

2024

[41] Prospects for an active optical clock based on cavityless lasing. Deshui Yu, Jia Zhang, Shougang Zhang, and Jingbiao Chen, Adv. Quantum Technol. 7, 2300308 (2024).

2023

[40] Entanglement-enhanced synchronous differential comparison. Deshui Yu, Jingbiao Chen, and Shougang Zhang, Physical Review A 107, 043120 (2023).

[39] Active whispering-gallery microclock in pulsed-operation mode. Deshui Yu, Jingbiao Chen, and Shougang Zhang, Physical Review A 107, 043712 (2023).

[38] Proposal for an active whispering-gallery microclock. Deshui Yu, Frank Vollmer, and Shougang Zhang, Quantum Science and Technology 8, 025005 (2023).

[37] Proposal for a hybrid clock system consisting of passive and active optical clocks and a fully stabilized microcomb. Deshui Yu, Frank Vollmer, Pascal Del’Haye, and Shougang Zhang, Optics Express 31, 6228-6240 (2023).

2022

[36] Active optomechanics. Deshui Yu and Frank Vollmer, Communications Physics 5, 61 (2022).

2021

[35] Whispering-gallery-mode sensors for biological and physical sensing. Deshui Yu, M. Humar, K. Meserve, R. C. Bailey, S. Nic Chormaic, and Frank Vollmer, Nature Reviews Methods Primers 1, 83 (2021).

[34] Microscale whispering-gallery-mode light sources with lattice-confined atoms. Deshui Yu and Frank Vollmer, Scientific Reports 11, 13899 (2021).

[33] Allan deviation tells the binding properties in single-molecule sensing with whispering-gallery-mode optical microcavities. Deshui Yu and Frank Vollmer, Physical Review Research 3, 023087 (2021).

[32] Spontaneous PT-symmetry breaking in lasing dynamics. Deshui Yu and F. Vollmer, Communications Physics 4, 77 (2021).

[31] Quantum nanophotonic and nanoplasmonic sensing: towards quantum optical bioscience laboratories on chip. J. Xavier, Deshui Yu, C. Jones, E. Zossimova, and F. Vollmer, Nanophotonics 10, 1387-1435 (2021).

2019

[30] Superradiance from lattice-confined atoms inside hollow core fibre. S. Okaba, Deshui Yu, L. Vincetti, F. Benabid, and H. Katori, Communications Physics 2, 136 (2019).

[29] Open Ising model perturbed by classical colored noise. Deshui Yu and R. Dumke, Physical Review A 100, 022124 (2019).

2018

[28] Nonlinear circuit quantum electrodynamics based on the charge-qubit–resonator interface. Deshui Yu, L. C. Kwek, L. Amico, and R. Dumke, Physical Review A 98, 033833 (2018).

[27] Relaxation of Rabi dynamics in a superconducting multiple-qubit circuit. Deshui Yu, L. C. Kwek, and R. Dumke, Journal of Physics Communications 2, 095001 (2018).

[26] Feedback control of persistent-current oscillation based on the atomic-clock technique. Deshui Yu and R. Dumke, Physical Review A 97, 053813 (2018).

[25] Stabilizing Rabi oscillation of a charge qubit via the atomic clock technique. Deshui Yu, A. Landra, L. C. Kwek, L. Amico, and R. Dumke, New Journal of Physics 20, 023031 (2018).

2017

[24] Superconducting atom chips: towards quantum hybridization. C. Hufnagel, A. Landra, L. C. Chean, Deshui Yu, R. Dumke, Quantum Photonic Devices Proc. SPIE 10358, 103580D (2017).

[23] Superconducting qubit-resonator-atom hybrid system. Deshui Yu, L. C. Kwek, L. Amico, R. Dumke, Quantum Science and Technology 2, 035005 (2017).

[22] Theoretical description of a micromaser in the ultrastrong-coupling regime. Deshui Yu, L. C. Kwek, L. Amico, and R. Dumke, Physical Review A 95, 053811 (2017).

2016

[21] Superconducting resonator and Rydberg atom hybrid system in the strong coupling regime. Deshui Yu, A. Landra, M. M. Valado, C. Hufnagel, L. C. Kwek, L. Amico, R. Dumke, Physical Review A 94, 062301 (2016).

[20] Quantum state transmission in a superconducting charge qubit-atom hybrid. Deshui Yu, M. M. Valado, C. Hufnagel, L. C. Kwek, L. Amico, R. Dumke, Scientific Reports 6, 38356 (2016).

[19] Charge-qubit-atom hybrid. Deshui Yu, M. M. Valado, C. Hufnagel, L. C. Kwek, L. Amico, and R. Dumke, Physical Review A 93, 042329 (2016).

[18] Two coupled one-atom lasers. Deshui Yu, Journal of the Optical Society of America B 33, 797-803 (2016).

[17] Properties of far-field fluorescence from an ensemble of interacting Sr atoms. Deshui Yu, Journal of Modern Optics 63, 428-442 (2016).

2014

[16] Superradiant phase transition in an atom-cavity system combined with intracavity parametric down conversion. Deshui Yu and S. Genway, Physical Review A 90, 043824 (2014).

[15] Single-photon emitter based on an ensemble of lattice-trapped interacting atoms. Deshui Yu, Physical Review A 89, 063809 (2014).

[14] Steady-state properties of a driven atomic ensemble with nonlocal dissipation. B. Olmos, Deshui Yu, and I. Lesanovsky, Physical Review A 89, 023616 (2014).

2013

[13] Long-range interacting many-body systems with alkaline-earth-metal atoms. B. Olmos, Deshui Yu, Y. Singh, F. Schreck, K. Bongs, and I. Lesanovsky, Physical Review Letters 110, 143602 (2013).

2012

[12] Multichannel ultracold collisions between metastable bosonic 88Sr and fermionic 87Sr atoms. Deshui Yu, Physical Review A 86, 032703 (2012).

[11] Collisional shifts in one- and two-dimensional shallow blue-detuned 87Sr optical lattice clocks. Deshui Yu, Physical Review A 85, 032705 (2012).

2011

[10] Multi-threshold second-order phase transition in laser. W. Zhuang, Deshui Yu, Z. Liu, J. Chen, Chinese Science Bulletin 56, 3812-3816 (2011).

[9] Photonic band structure of the three-dimensional 88Sr atomic lattice. Deshui Yu, Physical Review A 84, 043833 (2011).

[8] Quantum-limited phase-matching effect in a Λ-type laser system. Deshui Yu and J. Chen, Physical Review A 83, 063846 (2011).

2010

[7] Four-level superradiant laser with full atomic cooperativity. Deshui Yu and J. Chen, Physical Review A 81, 053809 (2010).

[6] Theory of quenching quantum fluctuations of a laser system with a ladder-type configuration. Deshui Yu and J. Chen, Physical Review A 81, 023818 (2010).

2008

[5] Laser theory with finite atom–field interacting time. Deshui Yu and J. Chen, Physical Review A 78, 013846 (2008).

[4] Variational approach for the Bose–Hubbard model. Deshui Yu and J. Chen, Chinese Physics Letters 25, 1792 (2008).

2007

[3] Magnetic-field-assisted stimulated laser cooling in the (1+3)-level atomic system. Deshui Yu and J. Chen, Physical Review A 76, 023425 (2007).

[2] Microlaser with Ramsey separated fields cavity. Deshui Yu, W. Zhuang, J. Chen, Chinese Physics Letters 24, 1498-1501 (2007).

[1] Optical clock with millihertz linewidth based on a phase-matching effect. Deshui Yu and J. Chen, Physical Review Letters 98, 050801 (2007).

Atomic molecular and optical physics

现指导学生

吴浩洋  硕士研究生  0702Z1-精密测量物理