Arpita Rakshit scite author profile

We show that coherence between two excited rovibrational states belonging to the same molecular electronic configuration arises quite naturally due to their interaction with electromagnetic vacuum. For initial preparation of a molecule in the desired rovibrational states, we propose to employ the method of ultracold photoassociation. Spontaneous decay of the excited molecule then gives rise to vacuum-induced coherence between the excited ro-vibrational states. We demonstrate theoretically an interesting interplay of effects due to vacuum-induced coherence and photoassociation. We apply our theory to photoassociation of bosonic ytterbium ( 174 Yb) atoms, which appear to be a promising system for exploring such interplay. The effects discussed here can be important for controlling decoherence and dissipation in molecular systems.

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Interactions and low-energy collisions between an alkali ion and an alkali atom of a different nucleus

Rakshit¹,

Ghanmi

Berriche

et al. 2016

J. Phys. B: At. Mol. Opt. Phys.

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We study theoretically interaction potentials and low-energy collisions between different alkali atoms and alkali ions. Specifically, we consider systems such as X + , where X( is either Li(Cs+) or Cs(Li+), Na(Cs+) or Cs(Na+) and Li(Rb+) or Rb(Li+). We calculate the molecular potentials of the ground and first two excited states of these three systems using a pseudopotential method and compare our results with those obtained by others. We derive ground-state scattering wave functions and analyze the cold collisional properties of these systems for a wide range of energies. We find that, in order to get convergent results for the total scattering cross sections for energies of the order 1 K, one needs to take into account at least 60 partial waves. The low-energy scattering properties calculated in this paper may serve as a precursor for experimental exploration of quantum collisions between an alkali atom and an alkali ion of a different nucleus.

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Suppression of power broadening in strong-coupling photoassociation in the presence of a Feshbach resonance

Deb

Rakshit

2009

J. Phys. B: At. Mol. Opt. Phys.

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Abstract.Photoassociation (PA) spectrum in the presence of a magnetic Feshbach resonance is analyzed. Nonperturbative solution of the problem yields analytical expressions for PA linewidth and shift which are applicable for arbitrary PA laser intensity and magnetic field tuning of Feshbach Resonance. We show that by tuning magnetic field close to Fano minimum, it is possible to suppress power broadening at increased laser intensities. This occurs due to quantum interference of PA transitions from unperturbed and perturbed continuum. Line narrowing at high laser intensities is accompanied by large spectral shifts. We briefly discuss important consequences of line narrowing in cold collisions.

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Optical Feshbach resonances through a molecular dark state: Efficient manipulation ofp-wave resonances in fermionicYb171atoms

et al. 2014

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In a recent experiment by Yamazaki et al. [Phys.Rev. A 87 010704 (R) (2013) ], p-wave optical Feshbach resonance in fermionic 171 Yb atoms using purely long-range molecular excited states has been demonstrated. We theoretically show that, if two purely long range excited states of 171 Yb are coupled to the ground-state continuum of scattering states with two lasers, then it is possible to significantly suppress photoassociative atom loss by a dark resonance in the excited states. We present a general theoretical framework for creating a dark state in electronically excited molecular potential for the purpose of increasing the efficiency of an optical Feshbach resonance. This can be accomplished by properly adjusting the relative intensity, phase, polarizations and frequency detunings of two lasers. We present selective numerical results on atom loss spectra, p-wave elastic and inelastic scattering cross sections of 171 Yb atoms to illustrate the effects of the molecular dark state on optical Feshbach resonance.

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Arpita Rakshit

Formation of cold molecular ions by radiative processes in cold ion-atom collisions

Vacuum-induced coherence in ultracold photoassociative rovibrational excitations

Interactions and low-energy collisions between an alkali ion and an alkali atom of a different nucleus

Suppression of power broadening in strong-coupling photoassociation in the presence of a Feshbach resonance

Optical Feshbach resonances through a molecular dark state: Efficient manipulation ofp-wave resonances in fermionicYb171atoms

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