Controlling the quantum stereodynamics of ultracold bimolecular reactions

被引：1

作者：

De Miranda M.H.G. ^{[1
]}

Chotia A. ^{[1
]}

Neyenhuis B. ^{[1
]}

Wang D. ^{[1
]}

Quéméner G. ^{[1
]}

Ospelkaus S. ^{[2
]}

Bohn J.L. ^{[1
]}

Ye J. ^{[1
,3
]}

Jin D.S. ^{[1
,4
]}

机构：

[1] Department of Physics, NIST, University of Colorado, Boulder

[2] Max Planck Institute of Quantum Optics

[3] Department of Physics, Chinese University of Hong Kong, Shatin, N.T.

[4] Institut für Quantenoptik, Leibniz Universität

来源：

Nature Physics | 2011年 / 7卷 / 6期

基金：

美国国家科学基金会;

关键词：

D O I：

10.1038/nphys1939

中图分类号：

学科分类号：

摘要：

Molecular collisions in the quantum regime represent a new opportunity to explore chemical reactions. Recently, atom-exchangereactions were observed in a trapped ultracold gas of KRb molecules. In an external electric field, these polar molecules can easily be oriented and the exothermic and barrierless bimolecular reactions, KRb+KRb → K 2 +Rb 2 , occur at a rate that rises steeply with increasing dipole moment. Here we demonstrate the suppression of the bimolecular chemical reaction rate by nearly two orders of magnitude when we use an optical lattice trap to confine the fermionic polar molecules in a quasi-two-dimensional, pancake-like geometry, with the dipoles oriented along the tight confinement direction. With the combination of sufficiently tight confinement and Fermi statistics of the molecules, two polar molecules can approach each other only in a 'side-by-side' collision under repulsive dipoleg-dipole interactions. The suppression of chemical reactions is a prerequisite for the realization of new molecule-based quantum systems. © 2011 Macmillan Publishers Limited. All rights reserved.

引用

页码：502 / 507

页数：5

共 34 条

[1]

Zare R.N., Laser control of chemical reactions, Science, 279, 5358, pp. 1875-1879, (1998)

[2]

Aldegunde J., De Miranda M.P., Haigh J.M., Kendrick B.K., Saez-Rabanos V., Aoiz F.J., How reactants polarization can be used to change and unravel chemical reactivity, Journal of Physical Chemistry A, 109, 28, pp. 6200-6217, (2005)

[3]

Gijsbertsen A., Linnartz H., Taatjes C.A., Stolte S., Quantum interference as the source of steric asymmetry and parity propensity rules in NO-rare gas inelastic scattering, Journal of the American Chemical Society, 128, 27, pp. 8777-8789, (2006)

[4]

Ospelkaus S., Et al., Quantum-state controlled chemical reactions of ultracold KRb molecules, Science, 327, pp. 853-857, (2010)

[5]

Ni K.-K., Et al., Dipolar collisions of polar molecules in the quantum regime, Nature, 464, pp. 1324-1328, (2010)

[6]

Buchler H.P., Et al., Strongly correlated 2D quantum phases with cold polar molecules: Controlling the shape of the interaction potential, Phys. Rev. Lett., 98, (2007)

[7]

Micheli A., Et al., Cold polar molecules in two-dimensional traps: Tailoring interactions with external fields for novel quantum phases, Phys. Rev. A, 76, (2007)

[8]

Pupillo G., Micheli A., Buchler H.P., Zoller P., Cold Molecules: Theory, Experiment, Applications, pp. 421-469, (2009)

[9]

Baranov M., Theoretical progress in many-body physics with ultracold dipolar gases, Phys. Rep., 464, pp. 71-111, (2008)

[10]

Lahaye T., Menotti C., Santos L., Lewenstein M., Pfau T., The physics of dipolar bosonic quantum gases, Rep. Prog. Phys., 72, (2009)

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