Near-threshold scaling of resonant inelastic collisions at ultralow temperatures

Abstract

We show that the cross sections for a broad range of resonant inelastic processes accompanied by excitation exchange (such as spin-exchange, F\"orster resonant, or angular momentum exchange) exhibit an unconventional near-threshold scaling E m12, where E is the collision energy, m12=m1'+m2'-m1-m2, and mi and mi' are the initial and final angular momentum projections of the colliding species (i=1,\,2). In particular, the inelastic cross sections for m12=0 transitions display an unconventional E0 scaling similar to that of elastic cross sections, and their rates vanish as T m12+1/2. For collisions dominated by even partial waves (such as those of identical bosons in the same internal state) the scaling is modified to σinel E m12 +1 if m12 is odd. We present accurate quantum scattering calculations that illustrate these modified threshold laws for resonant spin exchange in ultracold Rb+Rb and O2+O2 collisions. Our results illustrate that the threshold scaling of collision cross sections is determined only by the energetics of the underlying process (resonant vs. exothermic) rather than by whether the internal states of colliding particles is changed in the collision.