Quantum Metrology Lab
Quantum Metrology Lab
Hybrid Atom-Nanophotonics Lab
Hybrid Atom-Nanophotonics Lab

Publications — Papers

Google Scholar Google Scholar: Chun-Chia Chen · Shayne Bennetts

Selected publications

  1. C.-C. Chen, R. González Escudero, J. Minář, B. Pasquiou, S. Bennetts, F. Schreck*. PDF. Continuous Bose–Einstein condensation. Nature 606, 683–687 (2022). arXiv.
  2. C.-C. Chen, J. L. Siegel, B. D. Hunt, T. Grogan, Y. S. Hassan, K. Beloy, K. Gibble, R. C. Brown, A. D. Ludlow. Clock-line mediated Sisyphus cooling. Phys. Rev. Lett. 133, 053401 (2024).
  3. C.-C. Chen*, S. Bennetts*, F. Schreck. PDF. The path to continuous Bose-Einstein condensation. Advances in Atomic, Molecular, and Optical Physics 72, 361–430 (2023) — Book chapter.
  4. C.-C. Chen*, R. Takeuchi*, S. Okaba, H. Katori. Narrow-line mediated Sisyphus cooling in the 3P2 metastable state of strontium. Phys. Rev. Research 7, L022076 (2025).
  5. C.-C. Chen*, S. Bennetts*, R. González Escudero, B. Pasquiou, F. Schreck. Continuous guided strontium beam with high phase-space density. Phys. Rev. Applied 12, 044014 (2019). arXiv.
  6. C.-C. Chen, S. Bennetts, R. González Escudero, F. Schreck, B. Pasquiou*. Sisyphus optical lattice decelerator. Phys. Rev. A 100, 023401 (2019).
  7. S. Bennetts, C.-C. Chen, B. Pasquiou*, F. Schreck. PDF. Steady-State Magneto-Optical Trap with 100-Fold Improved Phase-Space Density. Phys. Rev. Lett. 119, 223202 (2017). arXiv.

All publications (most recent first)

  1. C.-C. Chen*, R. Takeuchi*, S. Okaba, H. Katori. Narrow-line mediated Sisyphus cooling in the 3P2 metastable state of strontium. Phys. Rev. Research 7, L022076 (2025).
  2. A Abdalla et al., Terrestrial very-long-baseline atom interferometry: summary of the second workshop. EPJ Quantum Technology 12 (1), 1–79 (2025).
  3. S. Dubey, G. A. Kazakov*, B. Heizenreder, S. Zhou, S. Bennetts, S. A. Schäffer, A. Sitaram, F. Schreck. Modeling of a continuous superradiant laser on the sub-mHz transition in neutral strontium-88. Phys. Rev. Research 7, 013292 (2025).
  4. F. Famà, S. Zhou, B. Heizenreder, M. Tang, S. Bennetts, S. B. Jäger, S. A. Schäffer, F. Schreck*. Continuous cavity QED with an atomic beam. Phys. Rev. A 110 (6), 063721 (2024).
  5. C.-C. Chen, J. L. Siegel, B. D. Hunt, T. Grogan, Y. S. Hassan, K. Beloy, K. Gibble, R. C. Brown, A. D. Ludlow. Clock-line mediated Sisyphus cooling. Phys. Rev. Lett. 133, 053401 (2024).

Before starting our Taiwan Lab

  1. J. L. Siegel, W. F. McGrew, Y. S. Hassan, C.-C. Chen, K. Beloy, T. Grogan, A. D. Ludlow. Excited-band coherent delocalization for improved optical lattice clock performance. Phys. Rev. Lett. 132, 133201 (2024).
  2. J. Samland, S. Bennetts, C.-C. Chen, R. González Escudero, F. Schreck, B. Pasquiou*. Optical pumping of 5s4d¹D₂ strontium atoms for laser cooling and imaging. Phys. Rev. Research 6, 013319 (2024). arXiv.
  3. C.-C. Chen*, S. Bennetts*, F. Schreck. The path to continuous Bose-Einstein condensation. Advances in Atomic, Molecular, and Optical Physics 72, 361–430 (2023) — Book chapter.
  4. C.-C. Chen, R. González Escudero, J. Minář, B. Pasquiou, S. Bennetts, F. Schreck*. Continuous Bose–Einstein condensation. Nature 606, 683–687 (2022). arXiv.
  5. X. Zhang, K. Beloy, Y. S. Hassan, W. F. McGrew, C.-C. Chen, J. L. Siegel, T. Grogan, A. D. Ludlow*. Subrecoil Clock-Transition Laser Cooling Enabling Shallow Optical Lattice Clocks. Phys. Rev. Lett. 129, 113202 (2022).
  6. R. González Escudero, C.-C. Chen, S. Bennetts, B. Pasquiou, F. Schreck*. Steady-state magneto-optical trap of fermionic strontium on a narrow-line transition. Phys. Rev. Research 3 (3), 033159 (2021).
  7. C.-C. Chen*, S. Bennetts*, R. González Escudero, B. Pasquiou, F. Schreck. Continuous guided strontium beam with high phase-space density. Phys. Rev. Applied 12, 044014 (2019). arXiv.
  8. C.-C. Chen, S. Bennetts, R. González Escudero, F. Schreck, B. Pasquiou*. Sisyphus optical lattice decelerator. Phys. Rev. A 100, 023401 (2019).
  9. O. Onishchenko*, S. Pyatchenkov, A. Urech, C.-C. Chen, S. Bennetts, G. A. Siviloglou, F. Schreck. Frequency of the ultranarrow 1S₀–3P₂ transition in ⁸⁷Sr. Phys. Rev. A 99 (5), 052503 (2019). arXiv.
  10. A. Ciamei, J. Szczepkowski, A. Bayerle, V. Barbé, L. Reichsöllner, C.-C. Chen, et al.. The RbSr 2 Σ+ ground state investigated via spectroscopy of hot and ultracold molecules. Phys. Chem. Chem. Phys. 20 (41), 26221–26240 (2018).
  11. S. Bennetts, C.-C. Chen, B. Pasquiou*, F. Schreck. Steady-State Magneto-Optical Trap with 100-Fold Improved Phase-Space Density. Phys. Rev. Lett. 119, 223202 (2017). arXiv.
  12. C.-Y. Huang, C.-C. Chen, L.-A. Sun, G.-B. Liao, K.-S. Wu, Y.-J. Lin, M.-S. Chang. A simple recipe for rapid all-optical formation of spinor Bose–Einstein condensates. J. Phys. B: At. Mol. Opt. Phys. 50 (15), 155302 (2017).
  13. A. Ciamei, A. Bayerle, C.-C. Chen, B. Pasquiou, F. Schreck. Efficient production of long-lived ultracold molecules. Phys. Rev. A 96 (1), 013406 (2017).

Older papers

  1. G. D. McDonald*, C. C. N. Kuhn, K. S. Hardman, S. Bennetts, P. J. Everitt, P. A. Altin, J. E. Debs, J. D. Close, N. P. Robins. A Bright Solitonic Matter-Wave Interferometer. Phys. Rev. Lett. 113, 013002 (2014).
  2. C. C. N. Kuhn, G. D. McDonald, K. S. Hardman, S. Bennetts, P. J. Everitt, P. A. Altin, J. E. Debs, J. D. Close, N. P. Robins*. A Bose-condensed, simultaneous dual species Mach–Zehnder atom interferometer. New Journal of Physics 16, 073035 (2014).
  3. G. D. McDonald*, C. C. N. Kuhn, S. Bennetts, J. E. Debs, K. S. Hardman, J. D. Close, N. P. Robins. A faster scaling in acceleration-sensitive atom interferometers. EPL (Europhysics Letters) 105, 63001 (2014).
  4. K. S. Hardman*, C. C. N. Kuhn, G. D. McDonald, J. E. Debs, S. Bennetts, J. D. Close, N. P. Robins. The Role of Source Coherence for Atom Interferometery. Phys. Rev. A 89, 023626 (2014).
  5. S. Bennetts*, G. D. McDonald, K. S. Hardman, J. E. Debs, C. C. N. Kuhn, J. D. Close, N. P Robins. External cavity diode lasers with 5 kHz linewidth, 200 nm tuning range at 1.55 μm, methods for linewidth measurement. Optics Express 22 (9), 10642–10654 (2014).
  6. K. S. Hardman*, S. Bennetts, J. E. Debs, C. C. N. Kuhn, G. D. McDonald, N. P. Robins. Construction, Characterization of External Cavity Diode Lasers for Atomic Physics. Journal of Visualized Experiments 86, e51184 (2014).
  7. G. D. McDonald*, C. C. N. Kuhn, S. Bennetts, J. E. Debs, K. S. Hardman, J. D. Close, N. P. Robins. 80 ħk Momentum Separation with Bloch Oscillations in an Optically Guided Atom Interferometer. Phys. Rev. A 88, 053620 (2013).
  8. G. D. McDonald*, H. Keal, P. A. Altin, J. E. Debs, S. Bennetts, C. C. N. Kuhn, K. S. Hardman, M. T. Johnsson, J. D. Close, N. P. Robins. Optically guided linear Mach–Zehnder atom interferometer. Phys. Rev. A 87, 013632 (2013).
  9. P. A. Altin, M. T. Johnsson, V. Negnevitsky, G. R. Dennis, R. Anderson, J. E. Debs, S. S. Szigeti, K. S. Hardman, S. Bennetts, G. D. McDonald, L. D. Turner, J. D. Close, N. P. Robins. Precision atomic gravimeter based on Bragg diffraction. New Journal of Physics 15, 023009 (2013).
  10. A. Hemming*, S. Bennetts, N. Simakov, A. Davidson, J. Haub, A. Carter. High power operation of cladding pumped holmium-doped silica fibre lasers. Optics Express 21 (4), 4560 (2013).
  11. A. Hemming*, J. Richards, A. Davidson, N. Carmody, S. Bennetts, N. Simakov, J. Haub. 99 W mid-IR operation of a ZGP OPO at 25% duty cycle. Optics Express 21 (8), 10062 (2013).
  12. S. S. Sané, S. Bennetts, J. E. Debs, C. C. N. Kuhn, G. D. McDonald, P. A. Altin, J. D. Close, N. P. Robins*. 11 W narrow linewidth laser source at 780 nm for laser cooling and manipulation of rubidium. Optics Express 20 (8), 10062 (2012).
  13. H.-C. Chuang, C.-R. Chang, C.-C. Chen, M.-S. Chang. An external cavity diode laser using a volume holographic grating. Optics & Laser Technology 44 (7), 2182–2185 (2012).
  14. A. Hemming*, S. D. Jackson, A. Sabella, S. Bennetts, D. G. Lancaster. High power, narrow bandwidth, broadly tunable Tm³+, Ho³+-co-doped aluminosilicate glass fibre laser. Electronics Letters 46 (24), 1617 (2010).
  15. N. Simakov*, A. Hemming, S. Bennetts, J. Haub. Efficient, polarised, gain-switched operation of a Tm-doped fibre laser. Optics Express 19 (16), 14949 (2010).
  16. A. Hemming*, J. Richards, S. Bennetts, A. Davidson, N. Carmody, P. Davies, L. Corena, D. Lancaster. A high power hybrid mid-IR laser source. Optics Communications 283 (20), 4041 (2010).
  17. K. S. Wu*, D. Ottaway, Jesper Munch, D. G. Lancaster, S. Bennetts, S. D. Jackson. Gain-switched holmium-doped fibre laser. Optics Express 17 (23), 20872 (2009).
  18. N. Jovanovic*, G. D. Marshall, A. Fuerbach, G. E. Town, S. Bennetts, D. G. Lancaster, M. J. Withford. Highly narrow linewidth, CW, all-fiber oscillator with a switchable linear polarization. IEEE Photonics Technology Letters 20 (10), 809 (2008).
  19. S. D. Jackson*, A. Sabella, A. Hemming, S. Bennetts, D. G. Lancaster*. High-power 83 W holmium-doped silica fiber laser operating with high beam quality. Optics Letters 32 (3), 241–243 (2007).