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

Abstract

We propose a method to suppress the chemical reactions between ultracold bosonic ground-state 23Na87Rb molecules based on optical shielding. By applying a laser with a frequency blue-detuned from the transition between the lowest rovibrational level of the electronic ground state X1+ (vX=0, jX=0), and the long-lived excited level b30 (vb=0, jb=1), the long-range dipole-dipole interaction between the colliding molecules can be engineered, 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 b30 (vb=0, jb=1) 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.