Orbital-resolved three-body recombination across a p-wave Feshbach resonance in ultracold 6Li
Abstract
We report precision, orbital-resolved measurements of three-body recombination near the 159~G p-wave Feshbach resonance in an ultracold gas of 6Li atoms prepared in their lowest hyperfine state. Using a radio-frequency gated protocol that suppresses magnetic-field transients below the milligauss level, we resolve loss features associated with the |m|=1 and m=0 orbital projections. The measured three-body loss coefficient L3 is well captured by a thermally averaged cascade-recombination model, enabling extraction of the resonance splitting δ B and effective-range parameter ke. At the lowest temperature, we obtain δ B = 7.6(3)~mG and ke = 0.151(6)\,a0-1, both in quantitative agreement with coupled-channel theory. These results establish orbital-resolved three-body spectroscopy as a precision probe of p-wave scattering and provide a benchmark for microscopic models of resonant few-body loss.
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