2004
DOI: 10.1140/epjd/e2004-00130-3
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Slow ammonia molecules in an electrostatic quadrupole guide

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Cited by 57 publications
(95 citation statements)
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References 31 publications
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“…3 and proofs the quadratic Stark shift of the guided molecules. Indeed, with the same apparatus it has been observed [4,6] that for H 2 CO and ND 3 (linear Stark molecules), the flux depends quadratically on V .…”
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confidence: 90%
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“…3 and proofs the quadratic Stark shift of the guided molecules. Indeed, with the same apparatus it has been observed [4,6] that for H 2 CO and ND 3 (linear Stark molecules), the flux depends quadratically on V .…”
mentioning
confidence: 90%
“…Avoided level crossings are neither expected nor found, and second-order perturbation theory is a reasonable approximation for the Stark shift computation of H 2 O and D 2 O. Moreover, since the contribution to the perturbation from each coupled pair of states is inversely proportional to the energy gap between the pair, the shift will be proportional to the density of (rotational) Our apparatus [4] is depicted in Fig. 2.…”
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confidence: 94%
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“…Tunneling becomes the dominant reaction pathway, leading the the exciting possibility of controlling chemical reactions [9,10]. Considerable progress has been made in the direct cooling of molecules, yielding larger numbers and colder temperatures in the millikelvin range [11][12][13]. In addition, photoassociation of bi-alkali mixtures has produced molecules already in the ultracold regime, though vibrationally hot [14,15].…”
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confidence: 99%
“…An additional annular guide around the periphery of the rotating disk enables continuous operation. The capabilities and the universality of our technique are demonstrated by deceleration of three species, CH 3 F, CF 3 H, and CF 3 CCH, from a liquid-nitrogen-cooled source [12] with different initial kinetic energies of the order of 100 K. Output beams with intensities of several 10 9 mm À2 s À1 for molecules with kinetic energies below 1 K are achieved. Even higher intensities are expected for molecules from a supersonic beam or a cryogenic buffer-gas cell [13,14].…”
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confidence: 99%