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Stevenson, Ian; Blasing, David; Chen, Yong P.; Elliott, Daniel S.

doi:10.1103/physreva.94.062503

Cited by 11 publications

(14 citation statements)

References 21 publications

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“…In particular, short-range photoassociation offers a simple optical pathway from atoms to molecules; it allows accumulation of cold molecules in the vibronic ground state, and can be applied to systems that are not amenable to magnetoassociation. Short-range PA has been implemented for various heteronuclear molecules [28][29][30][31][32] . We have recently formed polar 85 RbCs molecules in this way, trapped them optically, and measured atom-molecule collision rates 33 ) I n t e r n u c l e a r s e p a r a t i o n R ( Å ) lowed microwave (MW) transitions between neighbouring rotational states 35 , which may be driven with very high resolution.…”

Section: Introductionmentioning

confidence: 99%

Microwave coherent control of ultracold ground-state molecules formed by short-range photoassociation

Gong

et al. 2020

Phys. Chem. Chem. Phys.

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Section: Introductionmentioning

confidence: 99%

Microwave coherent control of ultracold ground-state molecules formed by short-range photoassociation

Gong

et al. 2020

Phys. Chem. Chem. Phys.

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“…There has been immense interest and progress in creating ultracold heteronuclear polar molecules [1][2][3][4][5][6][7][8][9][10][11][12] which, by virtue of their permanent electric dipole moment in the electronic ground state, are important for a variety of experiments not possible with ultracold atoms [13][14][15][16]. One-photon photoassociation (PA) of ultracold atoms [17] has been extensively used to create ultracold diatomic molecules in excited electronic states [12] and in many cases such molecules spontaneously decay to the electronic ground state [3,[18][19][20][21][22]. While this has been a successful strategy even for the formation of rovibronic ground state i.e.…”

Section: (Submitted 7 November 2016)mentioning

confidence: 99%

“…While this has been a successful strategy even for the formation of rovibronic ground state i.e. X 1 Σ + ( = 0) molecules of some species [3,20,21], the process always leads to molecules being formed in a distribution of vibrational and rotational states [18][19][20][21][22]. An alternative approach is to again start with ultracold atoms but use a coherent coupling scheme for the formation of molecules in a specific rovibronic state.…”

Section: (Submitted 7 November 2016)mentioning

confidence: 99%

“…We also calculated the efficiency for transfer to the X 1 Σ + ( = 43) level which has a binding energy of 137 cm -1 and a permanent electric dipole moment of ~1.5 Debye [34]. With the same laser powers and pulse sequence, but using as intermediate the B 1 Π ( = 20) level [35,51], located 125 GHz below the 7 Li (2s 2 S 1/2 ) + 85 Rb (5p 2 P 1/2 ) asymptote [22], we find a transfer efficiency of 1.7% that corresponds to 1.7 × 10 4 molecules in a single rovibrational X 1 Σ + ( = 43) level, starting with ~10 6 atoms. Such high efficiency is encouraging for all-optical production of ultracold molecules.…”

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confidence: 99%

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Two-photon photoassociation spectroscopy of an ultracold heteronuclear molecule

et al. 2017

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We report on two-photon photoassociation (PA) spectroscopy of ultracold heteronuclear LiRb molecules. This is used to determine the binding energies of the loosely bound levels of the electronic ground singlet and the lowest triplet states of LiRb. We observe strong two-photon PA lines with power broadened line widths greater than 20 GHz at relatively low laser intensity of 30 W/cm 2 . The implication of this observation on direct atom to molecule conversion using stimulated Raman adiabatic passage (STIRAP) is discussed and the prospect for electronic ground state molecule production is theoretically analyzed. The experiment is performed in a dual-species magnetooptical trap (MOT) apparatus for simultaneous cooling and trapping of 7 Li and 85 Rb atoms, the details of which are described elsewhere [35,36]. The 85 Rb MOT is operated as a dark spot MOT in order to reduce atom loss by light assisted collisions [35,36] and to optically pump 85 Rb atoms to the 5s 2 S 1/2 (F = 2) state. The 7 Li MOT is a traditional MOT where most of the atoms are in the 2s 2 S 1/2 (F = 2) state. The scheme used for Raman-type 2-photon PA spectroscopy is shown in Fig. 1(a). The frequency PA  of the PA laser is tuned to at a PA transition to create LiRb* molecules in a specific bound vibrational level near the Li (2s 2 S 1/2 ) + Rb (5p 2 P 1/2 ) atomic asymptote (* indicates electronically excited states). Molecule production leads to a reduction in the number of atoms trapped in the MOT and a corresponding reduction in atomic fluorescence [10,11]. We show an example of this trap loss signal in Fig. 2(a). With PA  held fixed on a PA resonance, the frequency R  of a second laser, called the Raman laser, is scanned across a bound-bound ↔ transition between the excited and ground electronic states of LiRb. When the frequency R  is resonant with the bound-bound transition, this field strongly couples the two levels and causes shifts (or splitting) in their energies due to a phenomenon commonly known as the Autler-Townes (AT) splitting. Due to the shift in the energy --

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“…In order to be implemented in future experiments, the present proposal now requires the spectroscopic characterization of the X 1 Σ + (v X = 0, j X = 0) → b 3 Π 0 (v b = 0, j b = 1) transition, namely its wavelength and its oscillator strength. While the X − b electronic transition has been experimentally studied for several species (LiRb [52], LiCs [53,54], NaK [55], NaRb [38], NaCs [56], KRb [57], KCs [58], RbCs [59]), these investigations are all performed at room temperatures, so that the rovibrational level (v X = 0, j X = 0) is not populated. Furthermore the forbidden character of the transition still needs to be carefully analyzed, which will be done in a forthcoming study.…”

mentioning

confidence: 99%

Optical shielding of destructive chemical reactions between ultracold ground-state NaRb molecules

Xie,

Lepers,

Vexiau

et al. 2020

Preprint

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We propose a method to suppress the chemical reactions between ultracold bosonic groundstate 23 Na 87 Rb molecules based on optical shielding. By applying a laser with a frequency bluedetuned from the transition between the lowest rovibrational level of the electronic ground state X 1 Σ + (vX = 0, jX = 0), and the long-lived excited level b 3 Π(v b = 0, j b = 1), we can engineer the long-range dipole-dipole interaction between the colliding molecules, leading to a dramatic suppression of reactive and photoinduced inelastic collisions, for both linear and circular laser polarizations. We demonstrate that the spontaneous emission from the long-lived b 3 Π(v b = 0, j b = 1) level does not deteriorate the shielding process. This opens the possibility for a strong increase of the lifetime of cold molecule traps, and for an efficient evaporative cooling. We also anticipate that the proposed mechanism is valid for alkali-metal diatomics with sufficiently large dipole-dipole interactions.

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C1Σ+, A1Σ+, and
Ian Stevenson
¹
,
David Blasing
²
,
Yong P. Chen
³

et al.

Cited by 11 publications

References 21 publications

Microwave coherent control of ultracold ground-state molecules formed by short-range photoassociation

Microwave coherent control of ultracold ground-state molecules formed by short-range photoassociation

Two-photon photoassociation spectroscopy of an ultracold heteronuclear molecule

Optical shielding of destructive chemical reactions between ultracold ground-state NaRb molecules

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C1Σ+, A1Σ+, andIan Stevenson1, David Blasing2, Yong P. Chen3 et al.

Cited by 11 publications

References 21 publications

Microwave coherent control of ultracold ground-state molecules formed by short-range photoassociation

Microwave coherent control of ultracold ground-state molecules formed by short-range photoassociation

Two-photon photoassociation spectroscopy of an ultracold heteronuclear molecule

Optical shielding of destructive chemical reactions between ultracold ground-state NaRb molecules

Contact Info

Product

Resources

About

C1Σ+, A1Σ+, and
Ian Stevenson
¹
,
David Blasing
²
,
Yong P. Chen
³

et al.