Abstract
Paraexcitons, the lowest energy exciton states in Cu2O, have been considered a good system for realizing exciton Bose–Einstein condensation (BEC). The fact that their BEC has not been attained so far is attributed to a collision-induced loss, whose nature remains unclear. To understand collisional properties of cold paraexcitons governing their BEC, we perform a theoretical analysis of the s-wave paraexciton–paraexciton scattering at low temperatures. We show the two-channel character of the scattering, where incoming paraexcitons are coupled to a biexciton in a closed channel. Being embedded in the paraexciton scattering continuum, the biexciton is a Feshbach resonance giving rise to a paraexciton loss and a diminution of their background scattering length. In strain-induced traps, the biexciton effects generally increase with stress. Thus the scattering length a of trapped paraexcitons decreases monotonically with stress turning its sign as stress goes beyond a critical value. In the stress range with a < 0, the paraexciton loss increases with stress, whereas in that with a > 0 the loss is almost stress-independent. Importantly, that in the latter case the loss rate can be reduced to such small values that it has no effects on BEC by lowering temperatures to near one Kelvin and below. Our approximate calculations give the critical value of stress in the range just above one kilobar; thus BEC of strain-confined paraexcitons might be attained under low stress at a subkelvin temperature.
Highlights
Exciton in semiconductors is a Coulomb-bound pair of an electron in the conduction band and a hole in the valence band
In the low-density limit, excitons behave as bosons, so they may undergo Bose-Einstein condensation (BEC) if their lifetime is long enough to allow the system to reach quasiequilibrium.[1−3] BEC is expected in Cu2O where the dipole-forbidden 1s excitons of the yellow series have relatively long lifetime
A stable paraexciton condensate might take place under experimental conditions of ref. 10 provided the applied stress S ≤ S0. It is the analogy of excitons with atoms that has motivated the search for BEC in Cu2O
Summary
Exciton in semiconductors is a Coulomb-bound pair of an electron in the conduction band and a hole in the valence band. To obtain salient features of the s-wave collision dominating scattering at low temperatures, we develop an approximate way of dealing with the nonlocal exchange part of interaction potentials in two channels, which is the coupling potential This makes it possible for us to estimate the paraexciton background scattering length, the binding energy of a biexciton supported by the closed channel as well as strength of the paraexciton-biexciton coupling. With this coupling the biexciton is not a bound state that can be detected, but a Feshbach resonance, which manifests itself through changes it makes to collisional properties of paraexcitons. Our results provide theoretical understanding of obstacles to paraexciton BEC, which offers interpretation of recent experimental results as well as suggests means to improve conditions for trapped paraexcitons to reach their BEC
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