Abstract
A type-II InAs/AlAs_{0.16}Sb_{0.84} multiple-quantum well sample is investigated for the photoexcited carrier dynamics as a function of excitation photon energy and lattice temperature. Time-resolved measurements are performed using a near-infrared pump pulse, with photon energies near to and above the band gap, probed with a terahertz probe pulse. The transient terahertz absorption is characterized by a multi-rise, multi-decay function that captures long-lived decay times and a metastable state for an excess-photon energy of >100 meV. For sufficient excess-photon energy, excitation of the metastable state is followed by a transition to the long-lived states. Excitation dependence of the long-lived states map onto a nearly-direct band gap (E{_g}) density of states with an Urbach tail below E{_g}. As temperature increases, the long-lived decay times increase <E{_g}, due to the increased phonon interaction of the unintentional defect states, and by phonon stabilization of the hot carriers >E{_g}. Additionally, Auger (and/or trap-assisted Auger) scattering above the onset of the plateau may also contribute to longer hot-carrier lifetimes. Meanwhile, the initial decay component shows strong dependence on excitation energy and temperature, reflecting the complicated initial transfer of energy between valence-band and defect states, indicating methods to further prolong hot carriers for technological applications.
Highlights
Improving the light-to-electric conversion efficiency is crucial to the development of semiconductor photovoltaics
Transient-absorption measurements of these InAs/AlAsSb multiple-quantum wells (MQWs) were performed at a single excitation energy above the lowest interband transition, leaving unresolved the exact origin of the various competing phonon- and electron-scattering mechanisms that can contribute to the longevity of hot c arriers[8, 17]
The energy and temperature dependence of the charge-carrier dynamics in the InAs/AlAs0.16Sb0.84 MQW are complicated due to the multiple hole subbands, the unusual interaction with phonons, the changing of the localization of the holes with temperature and the possible interaction with moderate numbers of defects that give a non-zero contribution to the dynamics below the band gap
Summary
Improving the light-to-electric conversion efficiency is crucial to the development of semiconductor photovoltaics. Bandgap engineering of monolithic structures to include quantum confinement enhances optical absorption[10], type-II band-aligned quantum wells spatially separate electrons and holes to increase the excited-state carrier lifetime[8, 11], and structures with highly contrasting media can reduce the cooling through phonons[12, 13]. These properties all occur in InAs/AlAs0.16Sb0.84 multiple-quantum wells (MQWs), where a hotcarrier distribution is shown along with extended carrier lifetimes as a result of inhibited phonon–phonon interactions[8]. This process resulted in minimal changes in the photoluminescence from the sample indicating no relaxation or introduction of strain
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