Laser cooling scheme for the carbon dimer (C 12 2)

Niccolò Bigagli; Daniel W. Savin; Sebastian Will

doi:10.1103/PhysRevA.105.L051301

Laser cooling scheme for the carbon dimer (C 12 2)

Niccolò Bigagli
, Daniel W. Savin
, Sebastian Will

Columbia University

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

Abstract

We report on a scheme for laser cooling of 12C2. We have calculated the branching ratios for cycling and repumping transitions and calculated the number of photon scatterings required to achieve deflection and laser cooling of a beam of C2 molecules under realistic experimental conditions. Our results demonstrate that C2 cooling using the Swan (d3Πg↔a3Πu) and so-called Duck (d3Πg↔c3ςu+) bands is achievable via techniques similar to state-of-the-art molecular cooling experiments. The Phillips (A1Πu↔X1ςg+) and Ballik-Ramsay (b3ςg-↔a3Πu) bands offer the potential for narrow-line cooling. This work opens up a path to cooling of molecules with carbon-carbon bonds and may pave the way toward quantum control of organic molecules.

Original language	English
Article number	L051301
Journal	Physical Review A
Volume	105
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevA.105.L051301
Publication status	Published - 1 May 2022
Externally published	Yes

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title = "Laser cooling scheme for the carbon dimer (C 12 2)",

abstract = "We report on a scheme for laser cooling of 12C2. We have calculated the branching ratios for cycling and repumping transitions and calculated the number of photon scatterings required to achieve deflection and laser cooling of a beam of C2 molecules under realistic experimental conditions. Our results demonstrate that C2 cooling using the Swan (d3Πg↔a3Πu) and so-called Duck (d3Πg↔c3ςu+) bands is achievable via techniques similar to state-of-the-art molecular cooling experiments. The Phillips (A1Πu↔X1ςg+) and Ballik-Ramsay (b3ςg-↔a3Πu) bands offer the potential for narrow-line cooling. This work opens up a path to cooling of molecules with carbon-carbon bonds and may pave the way toward quantum control of organic molecules.",

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AU - Savin, Daniel W.

AU - Will, Sebastian

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N2 - We report on a scheme for laser cooling of 12C2. We have calculated the branching ratios for cycling and repumping transitions and calculated the number of photon scatterings required to achieve deflection and laser cooling of a beam of C2 molecules under realistic experimental conditions. Our results demonstrate that C2 cooling using the Swan (d3Πg↔a3Πu) and so-called Duck (d3Πg↔c3ςu+) bands is achievable via techniques similar to state-of-the-art molecular cooling experiments. The Phillips (A1Πu↔X1ςg+) and Ballik-Ramsay (b3ςg-↔a3Πu) bands offer the potential for narrow-line cooling. This work opens up a path to cooling of molecules with carbon-carbon bonds and may pave the way toward quantum control of organic molecules.

AB - We report on a scheme for laser cooling of 12C2. We have calculated the branching ratios for cycling and repumping transitions and calculated the number of photon scatterings required to achieve deflection and laser cooling of a beam of C2 molecules under realistic experimental conditions. Our results demonstrate that C2 cooling using the Swan (d3Πg↔a3Πu) and so-called Duck (d3Πg↔c3ςu+) bands is achievable via techniques similar to state-of-the-art molecular cooling experiments. The Phillips (A1Πu↔X1ςg+) and Ballik-Ramsay (b3ςg-↔a3Πu) bands offer the potential for narrow-line cooling. This work opens up a path to cooling of molecules with carbon-carbon bonds and may pave the way toward quantum control of organic molecules.

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DO - 10.1103/PhysRevA.105.L051301

M3 - Article

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SN - 2469-9926

VL - 105

JO - Physical Review A

JF - Physical Review A

IS - 5

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Laser cooling scheme for the carbon dimer (C 12 2)

Abstract

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