2026 Jun Ye: Physics Researcher – H-Index, Publications & Awards

Discipline name	D-Index	World Ranking	Current World Ranking	National Ranking	Current National Ranking	Publications	Citations
Physics	142	382	367	218	209	994	72509

Discipline name

D-Index

World Ranking

Current World Ranking

National Ranking

Current National Ranking

Publications

Citations

Physics

142

382

367

218

209

994

72509

Overview

Jun Ye is affiliated with the University of Colorado Boulder in the United States and specializes in the field of Physics and Astronomy. Their research primarily focuses on Atomic and Molecular Physics, and Optics, encompassing 253 publications in this subfield.

The main topics of their work include:

Cold Atom Physics and Bose-Einstein Condensates
Atomic and Subatomic Physics Research
Advanced Frequency and Time Standards
Advanced Fiber Laser Technologies
Quantum Information and Cryptography
Quantum optics and atomic interactions
Quantum many-body systems

Jun Ye's publication record spans several prominent scientific venues, with notable contributions in:

arXiv (Cornell University), 39 publications
Physical Review Letters, 19 publications
Nature, 10 publications
Science, 8 publications
Physical review. A/Physical review, A, 7 publications

Frequent coauthors collaborating with Jun Ye include:

Dhruv Kedar
William R. Milner
Ana María Rey
E. Oelker
Tobias Bothwell

Some of Jun Ye's recent papers reflect a focus on precision measurement, quantum technologies, and fundamental physics. These include:

Resolving the gravitational redshift across a millimetre-scale atomic sample, 2022, Nature
Frequency ratio measurements at 18-digit accuracy using an optical clock network, 2021, Nature
An improved bound on the electron's electric dipole moment, 2023, Science
Precision Metrology Meets Cosmology: Improved Constraints on Ultralight Dark Matter from Atom-Cavity Frequency Comparisons, 2020, Physical Review Letters
A tweezer clock with half-minute atomic coherence at optical frequencies and high relative stability, 2020, arXiv (Cornell University)

Best Publications

Optical atomic clocks

Andrew D. Ludlow;Martin M. Boyd;Jun Ye;E. Peik

2218
Citations
A High Phase-Space-Density Gas of Polar Molecules

K.-K. Ni;S. Ospelkaus;M. H. G. de Miranda;A. Pe'er

2174
Citations
Direct link between microwave and optical frequencies with a 300 THz femtosecond laser comb

Scott A. Diddams;David J. Jones;Jun Ye;Steven T. Cundiff

1654
Citations
Cold and ultracold molecules: science, technology and applications

Lincoln D Carr;David DeMille;Roman V Krems;Jun Ye

1646
Citations
An optical lattice clock with accuracy and stability at the 10 −18 level

B. J. Bloom;B. J. Bloom;T. L. Nicholson;T. L. Nicholson;J. R. Williams;J. R. Williams;J. R. Williams;S. L. Campbell;S. L. Campbell

1381
Citations
Colloquium: Femtosecond optical frequency combs

Steven T. Cundiff;Jun Ye

1354
Citations
Quantum-State Controlled Chemical Reactions of Ultracold Potassium-Rubidium Molecules

S. Ospelkaus;K.-K. Ni;D. Wang;M. H. G. de Miranda

1082
Citations
Observation of dipolar spin-exchange interactions with lattice-confined polar molecules

Bo Yan;Bo Yan;Steven A. Moses;Steven A. Moses;Bryce Gadway;Bryce Gadway;Jacob P. Covey;Jacob P. Covey

970
Citations
Systematic evaluation of an atomic clock at 2 × 10 −18 total uncertainty

T. L. Nicholson;T. L. Nicholson;S. L. Campbell;S. L. Campbell;R. B. Hutson;R. B. Hutson;G. E. Marti;G. E. Marti

879
Citations
Two-orbital SU(N) magnetism with ultracold alkaline-earth atoms

Alexey Vyacheslavovich Gorshkov;M. Hermele;V. Gurarie;C Xu

869
Citations
A sub-40-mHz-linewidth laser based on a silicon single-crystal optical cavity

T. Kessler;C. Hagemann;C. Grebing;T. Legero

841
Citations
Sr lattice clock at 1 x 10(-16) fractional uncertainty by remote optical evaluation with a Ca clock.

A. D. Ludlow;T. Zelevinsky;G. K. Campbell;S. Blatt

790
Citations
Cavity opto-mechanics using an optically levitated nanosphere

D. E. Chang;C. A. Regal;S. B. Papp;D. J. Wilson

736
Citations
Dipolar collisions of polar molecules in the quantum regime

K.-K. Ni;S. Ospelkaus;S. Ospelkaus;D. Wang;G. Quéméner

726
Citations
A quantum network of clocks

Peter Kómár;Eric M. Kessler;Michael Bishof;Liang Jiang

722
Citations
Delivering the same optical frequency at two places: accurate cancellation of phase noise introduced by an optical fiber or other time-varying path.

Long-Sheng Ma;Peter Jungner;Jun Ye;John L. Hall

708
Citations
Femtosecond Optical Frequency Comb: Principle, Operation and Applications

Jun Ye;Steven T. Cundiff

681
Citations
Broadband Cavity Ringdown Spectroscopy for Sensitive and Rapid Molecular Detection

Michael J. Thorpe;Kevin D. Moll;R. Jason Jones;Benjamin Safdi

620
Citations
Phase-Coherent Frequency Combs in the Vacuum Ultraviolet via High-Harmonic Generation inside a Femtosecond Enhancement Cavity

R. Jason Jones;Kevin D. Moll;Michael J. Thorpe;Jun Ye

588
Citations
1.5 μm Lasers with Sub-10 mHz Linewidth

D. G. Matei;T. Legero;S. Häfner;C. Grebing

575
Citations