Coherent Bichromatic Force Deflection of Molecules

Kozyryev, Ivan; Baum, Louis; Aldridge, Leland; Yu, Phelan; Eyler, E. E.; Doyle, John M.

doi:10.1103/physrevlett.120.063205

Cited by 59 publications

(49 citation statements)

References 66 publications

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“…The newest members on the list of laser-coolable species are polyatomic species [7][8][9][10]. The linear triatomic species SrOH is a good candidate for laser cooling [11], and has been deflected by optical forces [12], opening the way for similar species such as CaOH and CaOCH 3 [13], and more besides. These species should expand opportunities for quantum information, sensing, and fundamental physics [9].…”

Section: Introductionmentioning

confidence: 99%

Ultracold collisions of polyatomic molecules: CaOH

Augustovičová

Bohn

2019

New J. Phys.

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Ultracold collisions of the polyatomic species CaOH are considered, in internal states where the collisions should be dominated by long-range dipole-dipole interactions. The computed rate constants suggest that evaporative cooling can be quite efficient for these species, provided they start at temperatures achievable by laser cooling. The rate constants are shown to become more favorable for evaporative cooling as the electric field increases. Moreover, long-range dimer states (CaOH) 2 * are predicated to occur, having lifetimes on the order of microseconds. which is exothermic by some 13 000 K. Ca(OH) 2 is a stable compound used in industrial applications like paper production and sewage treatment. It is not known whether the reaction (1) occurs at low temperatures in the gas phase. If it does, this is obviously a detriment to producing and maintaining a stable, ultracold gas of CaOH. We will disregard the possibility that the reaction occurs, both because the potential energy surface is unknown, and because, in the appropriate internal states, the molecules are expected to be shielded by the repulsive parts of the dipole-dipole interaction.This circumstance simplifies the description of scattering, and leads to certain common behaviors. In this article, exploiting the electric dipole moment of CaOH and considering a state that has a small parity doublet, we find that these behaviors still occur. The behaviors that we single out are: (1) a suppression of inelastic scattering at sufficiently high electric field and sufficiently low temperature, for states that can be optically trapped; and (2) a set of electric-field resonances, previously described as 'field linked states', [16,17] that could serve as an additional platform for controlling these species and their interaction.

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Section: Introductionmentioning

confidence: 99%

Ultracold collisions of polyatomic molecules: CaOH

Augustovičová

Bohn

2019

New J. Phys.

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“…After each photon absorption event, a molecule needs to return to the initial state via spontaneous emission for Doppler cooling to work, but it may be lost instead due to the abundance of accessible vibrational and rotational degrees of freedom [20,21]. This challenge has motivated the development of alternative techniques that rely on reducing the role of spontaneous emission relative to Doppler cooling, including Sisyphus cooling of molecules [18,23], bichromatic force slowing and cooling [16,24], and interferometric cooling [19].…”

Section: Introduction To Swap Coolingmentioning

confidence: 99%

Laser cooling with adiabatic transfer on a Raman transition

Greve

Thompson

2019

New J. Phys.

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Sawtooth Wave Adiabatic Passage (SWAP) laser cooling was recently demonstrated using a narrowlinewidth single-photon optical transition in atomic strontium and may prove useful for cooling other atoms and molecules. However, many atoms and molecules lack the appropriate narrow optical transition. Here we use such an atom, 87 Rb, to demonstrate that two-photon Raman transitions with arbitrarily-tunable linewidths can be used to achieve 1D SWAP cooling without significantly populating the intermediate excited state. Unlike SWAP cooling on a narrow transition, Raman SWAP cooling allows for a final 1D temperature well below the Doppler cooling limit (here, 25 times lower); and the effective excited state decay rate can be modified in time, presenting another degree of freedom during the cooling process. We also develop a generic model for Raman Landau-Zener transitions in the presence of small residual free-space scattering for future applications of SWAP cooling in other atoms or molecules.

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“…temperature was achieved by Λ-enhanced gray molasses and deep cooling with a single laser, both of which can cool CaF to several mK [27,28]. Besides, laser cooling and deceleration of molecules with stimulated force has also progressed a lot both theoretically and experimentally [29][30][31].As the common cooling method before molecules loaded into a type-II MOT, laser sweep slowing or whitelight slowing, both of which are used to compensate Doppler shift, are not a very efficient way for larger number of molecules. This causes the problem of the small number and the low density of trapped molecules in the type-II MOT.…”

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confidence: 99%

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A new route for laser cooling and trapping of cold molecules: Intensity-gradient cooling of MgF molecules using localized hollow beams

et al. 2020

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We propose a promising scheme to prepare ultracold MgF molecules from a slowed cold molecular beam by using three-dimensional pure intensity-gradient induced Sisyphus cooling. The cooling is based on a blue-detuned localized hollow beam and a weak repumping beam. We investigate the dynamic process in the trap with the method of the Monte-Carlo simulations, verifying the feasibility. Our results show that achieving sub-Doppler temperature should be possible in such a well-designed trap; the trapped MgF molecules with initial temperature of 1 mK can be directly cooled to the final equilibrium temperature of about m 46.5 K, well below the Doppler limit (about m 527.9 K for MgF); meanwhile, molecules with initial temperature of 14 mK can be even cooled to about m 68.7 K. + -) cooling [22,23], is totally different in type-II systems, because of the existence of the dark states. There are two main cooling mechanisms in such transitions, the gray molasses and the magnetically-assisted Sisyphus cooling, both of which are able to cool particles to below the Doppler limit [24,25]. On this basis, Truppe et al realized for the first time the cooling of molecules, well below the Doppler limit, using a three-dimensional blue-detuned molasses [26]. temperature was achieved by Λ-enhanced gray molasses and deep cooling with a single laser, both of which can cool CaF to several mK [27,28]. Besides, laser cooling and deceleration of molecules with stimulated force has also progressed a lot both theoretically and experimentally [29][30][31].As the common cooling method before molecules loaded into a type-II MOT, laser sweep slowing or whitelight slowing, both of which are used to compensate Doppler shift, are not a very efficient way for larger number of molecules. This causes the problem of the small number and the low density of trapped molecules in the type-II MOT. In order to produce a diverse set of dense, ultracold diatomic molecular species, it would be interesting and worthwhile to explore how to produce much larger numbers of trapped molecules. Here we propose a new scheme for the preparation of ultracold molecules, which consists of the Stark-decelerated molecules and a localized hollow optical trap, where sub-Doppler cooling works well. We bypass the Doppler cooling, and achieve the process from supersonic molecular beam to sub-Doppler cooling of molecules. The localized hollow optical trap has a strong cooling capacity, and it can derive ultracold trapped molecules with higher density.The cooling mechanism of a hollow optical trap is pure intensity-gradient cooling [32][33][34][35][36][37], another sub-Doppler cooling, which can also efficiently cool the molecules to the temperature of several photon recoils. The magnetic-field-assisted intensity-gradient cooling of molecules has first been observed in a one-dimensional standing wave, which have substantially reduced the transverse temperature of a SrF molecular beam [4]. Magnesium monofluoride (MgF) [38,39], due to its highly diagonal Franck-Condon factors (FCFs) and st...

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Coherent Bichromatic Force Deflection of Molecules

Cited by 59 publications

References 66 publications

Ultracold collisions of polyatomic molecules: CaOH

Ultracold collisions of polyatomic molecules: CaOH

Laser cooling with adiabatic transfer on a Raman transition

A new route for laser cooling and trapping of cold molecules: Intensity-gradient cooling of MgF molecules using localized hollow beams

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