Related papers: Resonant and first-order dipolar interactions between ultracold molecules in static and microwave electric fields

Resonant and first-order dipolar interactions between ultracold molecules in static and microwave electric fields

URL: http://arxiv.org/abs/2106.01610v1
Date: Thu, 3 Jun 2021 05:58:20 GMT
Title: Resonant and first-order dipolar interactions between ultracold molecules in static and microwave electric fields
Authors: Tijs Karman, Zoe Z. Yan, Martin Zwierlein
Abstract summary: We study collisions between ultracold polar molecules polarized by microwave or static electric fields. We calculate the loss in two-body collisions that is observable experimentally. Results are presented numerically for fermionic $23$Na$40$K and bosonic $23$Na$39$K molecules.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We theoretically study collisions between ultracold polar molecules that are polarized by microwave or static electric fields. We systematically study the dependence on field strength, microwave polarization, and detuning from rotational transitions. We calculate the loss in two-body collisions that is observable experimentally and compare to the results expected for purely first-order dipolar interactions. For ground state molecules polarized by a static electric field, the dynamics are accurately described by first-order dipolar interactions. For microwave dressing, instead, resonant dipolar collisions dominate the collision process, in which molecules reorient along the intermolecular axis and interact with the full strength of the transition dipole. For red detuning, reorientation can only be suppressed at extreme Rabi frequencies. For blue detuned microwaves, resonant dipolar interactions dominate even for high Rabi frequencies, leading to microwave shielding for circular polarization and structured losses due to resonances for linear polarization. The results are presented numerically for fermionic $^{23}$Na$^{40}$K and bosonic $^{23}$Na$^{39}$K molecules.

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