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

Norrgard, Eric; McCarron, Daniel; Steinecker, Matthew; Tarbutt, M. R.; DeMille, David

doi:10.1103/physrevlett.116.063004

Cited by 178 publications

(234 citation statements)

References 45 publications

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“…At present, coherent association of ultracold alkali-metal atoms remains the only experimental technique to produce ultracold gases of polar molecules KRb and NaK [11][12][13]. Recent advances in laser cooling and magneto-optical trapping [14][15][16][17][18], single-photon cooling [19], Sisyphus laser cooling [20,21], and optoelectrical cooling [21,22] made it possible to control and confine molecular species such as SrF, CaF, SrOH, YO, CH 3 F, and H 2 CO in electrostatic and magnetic traps at temperatures as low as a fraction of a milliKelvin [14-19, 21, 22]. Due to the intrinsic limitations of optical cooling, it is necessary to employ second-stage cooling techniques to further reduce the temperature of a trapped molecular gas to <0.1 mK [1,19].…”

Section: Introductionmentioning

confidence: 99%

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Cold collisions of heavy Σ2 molecules with alkali-metal atoms in a magnetic field: Ab initio analysis and prospects for sympathetic cooling of SrOH(
Morita
¹
,
Kłos
²
,
Buchachenko
³

et al. 2017
Phys. Rev. A
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44
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Section: Introductionmentioning

confidence: 99%

“…[34] for a detailed discussion). As a result, it remains unclear whether heavy molecular radicals trapped in recent experiments [14][15][16][17][18][19] have small enough inelastic collision rates with ultracold alkali-metal atoms to allow for efficient sympathetic cooling in a magnetic trap.…”

Section: Introductionmentioning

confidence: 99%

Cold collisions of heavy Σ2 molecules with alkali-metal atoms in a magnetic field: Ab initio analysis and prospects for sympathetic cooling of SrOH(
Morita
¹
,
Kłos
²
,
Buchachenko
³

et al. 2017
Phys. Rev. A
25
2
44
1
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“…For example, the current state-of-the-art for the molecular magneto-optical trap (MOT) [27,28,29] is about 2000 molecules of SrF at ∼ 400 µK [30], corresponding to a phase-space density orders of magnitude smaller than typical atomic alkali MOTs of 10 9 −10 10 atoms at ∼ 10 µK. Many other techniques have also been employed to create cold molecules, such as photoassociation [31], buffer gas cooling [32], Stark deceleration [33,34], and Sisyphus cooling [35]; however, the achieved phase-space densities are all very far from that required for quantum degeneracy.…”

mentioning

confidence: 99%

New frontiers for quantum gases of polar molecules

et al. 2016

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The field of ultracold quantum matter has burgeoned over the last few decades, thanks to the growing capabilities for atomic systems to be probed and manipulated with exquisite control. Researchers can now precisely create and study quantum manybody states that are effectively isolated from the external environment. Much of the work in ultracold matter has focused on systems of alkali or alkaline-earth atoms, mainly due to their ease of cooling. Extending this precise control to molecules has seen rapidly increasing interest and activity, as molecules possess additional degrees of freedom that make them useful for tests of fundamental physics, studying ultracold chemistry and collisions, and engineering qualitatively new types of quantum phases and quantum many-body systems. Here, we review one particularly fruitful research direction: the creation and manipulation of ultracold bialkali molecules. The recent success in creating a quantum gas of polar molecules opens many exciting research opportunities. Atomic, Molecular, and Optical (AMO) systems offer experimentalists the ability to precisely control interactions in a quantum many-body system [1,2], and a rich set of experiments has already been performed. Some prominent examples include studies of the BEC-BCS crossover in two-component Fermi gases [3,4,5] and the superfluid-Mott insulator transition in ultracold bosons loaded into a 3D optical lattice [6]. Neutral atomic systems normally have point-like contact interactions that can be parametrized with a single quantity, the scattering length a, which can be tuned via a Feshbach resonance [2]. In recent years, systems with long-range and anisotropic interactions have garnered much attention. One natural example is the dipolar interaction between polar molecules, which is the focus of this Review. Of course, many other experimental platforms are also being pursued that feature long-range interactions, including highly magnetic atoms [7,8], trapped ions The dipolar interaction exhibits several important attributes. First, the energy scales in dipolar systems are usually much larger than those in typical atomic alkali systems, making it easier to study interaction-driven structural properties and non-equilibrium dynamics. Second, and perhaps more importantly, the anisotropic and long-range nature of the interaction allows for the realization of novel quantum phases, especially when the spatial dimensions of the system can be varied with optical lattices. Some of these engineered systems may find relevance to outstanding problems in condensed-matter physics [13,14]; moreover, qualitatively new types of physics can emerge in the presence of long-range interactions [15,16,17,18,19,20,21]. As a specific example of a unique feature of long-range interactions, a spin-1/2 Hamiltonian can be encoded based on a pair of oppositeparity rotational states where dipolar interactions give rise to a direct spin exchange coupling between molecules [22,23]. With this scheme implemented in an optical lattice, many-body spin dynam...

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“…The advantage of molecular eEDM experiments is in the large values of the effective electric field, several orders of magnitude higher than those in atoms [17,18,87,88]. Current progress in cooling and trapping molecules [89][90][91][92][93], as well as molecular ions [94,95], may soon allow one to increase coherence times and improve population control in molecular experiments, which might translate into a significant advantage of molecular experiments over atomic ones.…”

Section: Discussionmentioning

confidence: 99%

Electric dipole moments of superheavy elements: A case study on copernicium

et al. 2016

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The multiconfiguration Dirac-Hartree-Fock method was employed to calculate the atomic electric dipole moments (EDMs) of the superheavy element copernicium (Cn, Z = 112). The EDM enhancement factors of Cn, calculated here, are about one order of magnitude larger than those of Hg. The exponential dependence of the enhancement factors on the atomic number Z along group 12 of the periodic table was derived from the EDMs of the entire homologous series, Zn, Cd, Hg, Cn, and Uhb. These results show that superheavy elements with sufficiently long half-lives are potential candidates for EDM searches.

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

Cited by 178 publications

References 45 publications

Cold collisions of heavy Σ2 molecules with alkali-metal atoms in a magnetic field: Ab initio analysis and prospects for sympathetic cooling of SrOH(
Morita
¹
,
Kłos
²
,
Buchachenko
³

et al. 2017
Phys. Rev. A
25
2
44
1
View full text Add to dashboard Cite

Cold collisions of heavy Σ2 molecules with alkali-metal atoms in a magnetic field: Ab initio analysis and prospects for sympathetic cooling of SrOH(
Morita
¹
,
Kłos
²
,
Buchachenko
³

et al. 2017
Phys. Rev. A
25
2
44
1
View full text Add to dashboard Cite

New frontiers for quantum gases of polar molecules

Electric dipole moments of superheavy elements: A case study on copernicium

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

Cited by 178 publications

References 45 publications

Cold collisions of heavy Σ2 molecules with alkali-metal atoms in a magnetic field: Ab initio analysis and prospects for sympathetic cooling of SrOH(Morita1, Kłos2, Buchachenko3 et al. 2017Phys. Rev. A252441View full textAdd to dashboardCite

Cold collisions of heavy Σ2 molecules with alkali-metal atoms in a magnetic field: Ab initio analysis and prospects for sympathetic cooling of SrOH(Morita1, Kłos2, Buchachenko3 et al. 2017Phys. Rev. A252441View full textAdd to dashboardCite

New frontiers for quantum gases of polar molecules

Electric dipole moments of superheavy elements: A case study on copernicium

Contact Info

Product

Resources

About

Cold collisions of heavy Σ2 molecules with alkali-metal atoms in a magnetic field: Ab initio analysis and prospects for sympathetic cooling of SrOH(
Morita
¹
,
Kłos
²
,
Buchachenko
³

et al. 2017
Phys. Rev. A
25
2
44
1
View full text Add to dashboard Cite

Cold collisions of heavy Σ2 molecules with alkali-metal atoms in a magnetic field: Ab initio analysis and prospects for sympathetic cooling of SrOH(
Morita
¹
,
Kłos
²
,
Buchachenko
³

et al. 2017
Phys. Rev. A
25
2
44
1
View full text Add to dashboard Cite