Daniel McCarron scite author profile

Laser cooling and trapping are central to modern atomic physics. The most used technique in cold-atom physics is the magneto-optical trap (MOT), which combines laser cooling with a restoring force from radiation pressure. For a variety of atomic species, MOTs can capture and cool large numbers of particles to ultracold temperatures (less than ∼1 millikelvin); this has enabled advances in areas that range from optical clocks to the study of ultracold collisions, while also serving as the ubiquitous starting point for further cooling into the regime of quantum degeneracy. Magneto-optical trapping of molecules could provide a similarly powerful starting point for the study and manipulation of ultracold molecular gases. The additional degrees of freedom associated with the vibration and rotation of molecules, particularly their permanent electric dipole moments, allow a broad array of applications not possible with ultracold atoms. Spurred by these ideas, a variety of methods has been developed to create ultracold molecules. Temperatures below 1 microkelvin have been demonstrated for diatomic molecules assembled from pre-cooled alkali atoms, but for the wider range of species amenable to direct cooling and trapping, only recently have temperatures below 100 millikelvin been achieved. The complex internal structure of molecules complicates magneto-optical trapping. However, ideas and methods necessary for creating a molecular MOT have been developed recently. Here we demonstrate three-dimensional magneto-optical trapping of a diatomic molecule, strontium monofluoride (SrF), at a temperature of approximately 2.5 millikelvin, the lowest yet achieved by direct cooling of a molecule. This method is a straightforward extension of atomic techniques and is expected to be viable for a significant number of diatomic species. With further development, we anticipate that this technique may be employed in any number of existing and proposed molecular experiments, in applications ranging from precision measurement to quantum simulation and quantum information to ultracold chemistry.

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Dual-species Bose-Einstein condensate ofRb87andCs133
McCarron
¹
,
Cho
²
,
Jenkin
³

et al. 2011
Phys. Rev. A
248
12
268
0
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Submillikelvin Dipolar Molecules in a Radio-Frequency Magneto-Optical Trap

et al. 2016

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We demonstrate a scheme for magneto-optically trapping strontium monofluoride (SrF) molecules at temperatures one order of magnitude lower and phase space densities 3 orders of magnitude higher than obtained previously with laser-cooled molecules. In our trap, optical dark states are destabilized by rapidly and synchronously reversing the trapping laser polarizations and the applied magnetic field gradient. The number of molecules and trap lifetime are also significantly improved from previous work by loading the trap with high laser power and then reducing the power for long-term trapping. With this procedure, temperatures as low as 400 μK are achieved.

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Improved magneto–optical trapping of a diatomic molecule

et al. 2015

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We present experimental results from a new scheme for magnetooptically trapping strontium monofluoride (SrF) molecules, which provides increased confinement compared to our original work. The improved trap employs a new approach to magneto-optical trapping presented by M. Tarbutt, arXiv preprint 1409.0244, which provided insight for the first time into the source of the restoring force in magneto-optical traps (MOTs) where the cycling transition includes dark Zeeman sublevels (known as type-II MOTs). We measure a radial spring constant 20× greater than in our original work with SrF, comparable to the spring constants reported in atomic type-II MOTs. We achieve a trap lifetime τ MOT = 136(2) ms, over 2× longer than originally reported for SrF. Finally, we demonstrate further cooling of the trapped molecules by briefly increasing the trapping lasers' detunings. Our trapping scheme remains a straightforward extension of atomic techniques and marks a step towards the direct production of large, dense, ultracold molecular gases via laser cooling.

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Modulation transfer spectroscopy in atomic rubidium

McCarron

King

Cornish

2008

Meas. Sci. Technol.

151

106

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We report modulation transfer spectroscopy on the D2 transitions in 85 Rb and 87 Rb using a simple home-built electro-optic modulator (EOM). We show that both the gradient and amplitude of modulation transfer spectroscopy signals, for the 87 Rb F = 2 → F = 3 and the 85 Rb F = 3 → F = 4 transitions, can be significantly enhanced by expanding the beams, improving the signals for laser frequency stabilization. The signal gradient for these transitions is increased by a factor of 3 and the peak to peak amplitude was increased by a factor of 2. The modulation transfer signal for the 85 Rb F = 2 → F transitions is also presented to highlight how this technique can generate a single, clear line for laser frequency stabilization even in cases where there are a number of closely spaced hyperfine transitions.

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Daniel McCarron

Magneto-optical trapping of a diatomic molecule

Dual-species Bose-Einstein condensate ofRb87andCs133
McCarron
¹
,
Cho
²
,
Jenkin
³

et al. 2011
Phys. Rev. A
248
12
268
0
View full text Add to dashboard Cite

Submillikelvin Dipolar Molecules in a Radio-Frequency Magneto-Optical Trap

Improved magneto–optical trapping of a diatomic molecule

Modulation transfer spectroscopy in atomic rubidium

Contact Info

Product

Resources

About

Daniel McCarron

Magneto-optical trapping of a diatomic molecule

Dual-species Bose-Einstein condensate ofRb87andCs133McCarron1, Cho2, Jenkin3 et al. 2011Phys. Rev. A248122680View full textAdd to dashboardCite

Submillikelvin Dipolar Molecules in a Radio-Frequency Magneto-Optical Trap

Improved magneto–optical trapping of a diatomic molecule

Modulation transfer spectroscopy in atomic rubidium

Contact Info

Product

Resources

About

Dual-species Bose-Einstein condensate ofRb87andCs133
McCarron
¹
,
Cho
²
,
Jenkin
³

et al. 2011
Phys. Rev. A
248
12
268
0
View full text Add to dashboard Cite