2D transverse laser cooling of a hexapole focused beam of cold BaF molecules

NL-eEDM Collaboration; J. W.F. van Hofslot; I. E. Thompson; A. Touwen; N. Balasubramanian; R. Bause; H. L. Bethlem; A. Borschevsky; T. H. Fikkers; S. Hoekstra; S. A. Jones; J. E.J. Levenga; M. C. Mooij; H. Mulder; B. A. Nijman; E. H. Prinsen; B. J. Schellenberg; L. van Sloten; R. G.E. Timmermans; W. Ubachs; J. de Vries; L. Willmann

doi:10.1038/s42005-025-02470-x

2D transverse laser cooling of a hexapole focused beam of cold BaF molecules

NL-eEDM Collaboration
, J. W.F. van Hofslot
, I. E. Thompson
, A. Touwen
, N. Balasubramanian
, R. Bause
, H. L. Bethlem
, A. Borschevsky
, T. H. Fikkers
, S. Hoekstra^*
, S. A. Jones
, J. E.J. Levenga
, M. C. Mooij
, H. Mulder
, B. A. Nijman
, E. H. Prinsen
, B. J. Schellenberg
, L. van Sloten
, R. G.E. Timmermans
, W. Ubachs

J. de Vries, L. Willmann

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

2 Citations (Scopus)

3 Downloads (Pure)

Abstract

Laser cooling of molecules is a powerful technique for producing cold, slow beams for precision measurements and quantum control, yet its implementation remains challenging due to molecular complexity. Here, we combine a cryogenic buffer gas beam, an electrostatic hexapole lens, and 2D transverse Doppler laser cooling to produce a bright beam of barium monofluoride (¹³⁸Ba¹⁹F) molecules. We study both numerically and experimentally the laser cooling effect as a function of laser detuning, laser power, laser alignment, and interaction time. We find a scattering rate of 6.1(1.4) × 10⁵ s⁻¹ on the laser cooling transition (14% of the expected maximum) and identify suboptimal dark Zeeman state remixing, suboptimal laser sideband powers and detunings, and a lack of vibrational repump laser intensity as possible causes of such a low rate. Using 3 tuneable lasers with appropriate sidebands and detuning, each molecule scatters approximately 400 photons during 2D laser cooling, limited by the interaction time and scattering rate. Leaks to dark states are less than 10%. Finally, we use the experimental results to benchmark the trajectory simulations to predict the achievable flux 3.5 m downstream for a planned eEDM experiment.

Original language	English
Article number	40
Number of pages	10
Journal	Communications Physics
Volume	9
Issue number	1
DOIs	https://doi.org/10.1038/s42005-025-02470-x
Publication status	Published - 12-Jan-2026

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NL-eEDM Collaboration, van Hofslot, J. W. F., Thompson, I. E., Touwen, A., Balasubramanian, N., Bause, R., Bethlem, H. L., Borschevsky, A., Fikkers, T. H., Hoekstra, S., Jones, S. A., Levenga, J. E. J., Mooij, M. C., Mulder, H., Nijman, B. A., Prinsen, E. H., Schellenberg, B. J., van Sloten, L., Timmermans, R. G. E., ... Willmann, L. (2026). 2D transverse laser cooling of a hexapole focused beam of cold BaF molecules. Communications Physics, 9(1), Article 40. https://doi.org/10.1038/s42005-025-02470-x

@article{974a5b990f064339997b7e48cf6c322d,

title = "2D transverse laser cooling of a hexapole focused beam of cold BaF molecules",

abstract = "Laser cooling of molecules is a powerful technique for producing cold, slow beams for precision measurements and quantum control, yet its implementation remains challenging due to molecular complexity. Here, we combine a cryogenic buffer gas beam, an electrostatic hexapole lens, and 2D transverse Doppler laser cooling to produce a bright beam of barium monofluoride (138Ba19F) molecules. We study both numerically and experimentally the laser cooling effect as a function of laser detuning, laser power, laser alignment, and interaction time. We find a scattering rate of 6.1(1.4) × 105 s−1 on the laser cooling transition (14\% of the expected maximum) and identify suboptimal dark Zeeman state remixing, suboptimal laser sideband powers and detunings, and a lack of vibrational repump laser intensity as possible causes of such a low rate. Using 3 tuneable lasers with appropriate sidebands and detuning, each molecule scatters approximately 400 photons during 2D laser cooling, limited by the interaction time and scattering rate. Leaks to dark states are less than 10\%. Finally, we use the experimental results to benchmark the trajectory simulations to predict the achievable flux 3.5 m downstream for a planned eEDM experiment.",

author = "\{NL-eEDM Collaboration\} and \{van Hofslot\}, \{J. W.F.\} and Thompson, \{I. E.\} and A. Touwen and N. Balasubramanian and R. Bause and Bethlem, \{H. L.\} and A. Borschevsky and Fikkers, \{T. H.\} and S. Hoekstra and Jones, \{S. A.\} and Levenga, \{J. E.J.\} and Mooij, \{M. C.\} and H. Mulder and Nijman, \{B. A.\} and Prinsen, \{E. H.\} and Schellenberg, \{B. J.\} and \{van Sloten\}, L. and Timmermans, \{R. G.E.\} and W. Ubachs and \{de Vries\}, J. and L. Willmann",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2026.",

year = "2026",

month = jan,

day = "12",

doi = "10.1038/s42005-025-02470-x",

language = "English",

volume = "9",

journal = "Communications Physics",

issn = "0010-3616",

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NL-eEDM Collaboration, van Hofslot, JWF, Thompson, IE, Touwen, A, Balasubramanian, N, Bause, R, Bethlem, HL , Borschevsky, A , Fikkers, TH , Hoekstra, S , Jones, SA, Levenga, JEJ, Mooij, MC, Mulder, H, Nijman, BA, Prinsen, EH , Schellenberg, BJ, van Sloten, L, Timmermans, RGE, Ubachs, W, de Vries, J & Willmann, L 2026, '2D transverse laser cooling of a hexapole focused beam of cold BaF molecules', Communications Physics, vol. 9, no. 1, 40. https://doi.org/10.1038/s42005-025-02470-x

TY - JOUR

T1 - 2D transverse laser cooling of a hexapole focused beam of cold BaF molecules

AU - NL-eEDM Collaboration

AU - van Hofslot, J. W.F.

AU - Thompson, I. E.

AU - Touwen, A.

AU - Balasubramanian, N.

AU - Bause, R.

AU - Bethlem, H. L.

AU - Borschevsky, A.

AU - Fikkers, T. H.

AU - Hoekstra, S.

AU - Jones, S. A.

AU - Levenga, J. E.J.

AU - Mooij, M. C.

AU - Mulder, H.

AU - Nijman, B. A.

AU - Prinsen, E. H.

AU - Schellenberg, B. J.

AU - van Sloten, L.

AU - Timmermans, R. G.E.

AU - Ubachs, W.

AU - de Vries, J.

AU - Willmann, L.

PY - 2026/1/12

Y1 - 2026/1/12

N2 - Laser cooling of molecules is a powerful technique for producing cold, slow beams for precision measurements and quantum control, yet its implementation remains challenging due to molecular complexity. Here, we combine a cryogenic buffer gas beam, an electrostatic hexapole lens, and 2D transverse Doppler laser cooling to produce a bright beam of barium monofluoride (138Ba19F) molecules. We study both numerically and experimentally the laser cooling effect as a function of laser detuning, laser power, laser alignment, and interaction time. We find a scattering rate of 6.1(1.4) × 105 s−1 on the laser cooling transition (14% of the expected maximum) and identify suboptimal dark Zeeman state remixing, suboptimal laser sideband powers and detunings, and a lack of vibrational repump laser intensity as possible causes of such a low rate. Using 3 tuneable lasers with appropriate sidebands and detuning, each molecule scatters approximately 400 photons during 2D laser cooling, limited by the interaction time and scattering rate. Leaks to dark states are less than 10%. Finally, we use the experimental results to benchmark the trajectory simulations to predict the achievable flux 3.5 m downstream for a planned eEDM experiment.

AB - Laser cooling of molecules is a powerful technique for producing cold, slow beams for precision measurements and quantum control, yet its implementation remains challenging due to molecular complexity. Here, we combine a cryogenic buffer gas beam, an electrostatic hexapole lens, and 2D transverse Doppler laser cooling to produce a bright beam of barium monofluoride (138Ba19F) molecules. We study both numerically and experimentally the laser cooling effect as a function of laser detuning, laser power, laser alignment, and interaction time. We find a scattering rate of 6.1(1.4) × 105 s−1 on the laser cooling transition (14% of the expected maximum) and identify suboptimal dark Zeeman state remixing, suboptimal laser sideband powers and detunings, and a lack of vibrational repump laser intensity as possible causes of such a low rate. Using 3 tuneable lasers with appropriate sidebands and detuning, each molecule scatters approximately 400 photons during 2D laser cooling, limited by the interaction time and scattering rate. Leaks to dark states are less than 10%. Finally, we use the experimental results to benchmark the trajectory simulations to predict the achievable flux 3.5 m downstream for a planned eEDM experiment.

UR - https://www.scopus.com/pages/publications/105032163913

U2 - 10.1038/s42005-025-02470-x

DO - 10.1038/s42005-025-02470-x

M3 - Article

AN - SCOPUS:105032163913

SN - 0010-3616

VL - 9

JO - Communications Physics

JF - Communications Physics

IS - 1

M1 - 40

ER -

2D transverse laser cooling of a hexapole focused beam of cold BaF molecules

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