Abstract
Lead-free silver–bismuth semiconductors have become increasingly popular materials for optoelectronic applications, building upon the success of lead halide perovskites. In these materials, charge-lattice couplings fundamentally determine charge transport, critically affecting device performance. In this study, we investigate the optoelectronic properties of the recently discovered lead-free semiconductor Cu2AgBiI6 using temperature-dependent photoluminescence, absorption, and optical-pump terahertz-probe spectroscopy. We report ultrafast charge-carrier localization effects, evident from sharp THz photoconductivity decays occurring within a few picoseconds after excitation and a rise in intensity with decreasing temperature of long-lived, highly Stokes-shifted photoluminescence. We conclude that charge carriers in Cu2AgBiI6 are subject to strong charge-lattice coupling. However, such small polarons still exhibit mobilities in excess of 1 cm2 V–1 s–1 at room temperature because of low energetic barriers to formation and transport. Together with a low exciton binding energy of ∼29 meV and a direct band gap near 2.1 eV, these findings highlight Cu2AgBiI6 as an attractive lead-free material for photovoltaic applications.
Highlights
Lead-free silver−bismuth semiconductors have become increasingly popular materials for optoelectronic applications, building upon the success of lead halide perovskites
D evelopments in the field of lead-halide perovskites over the past decade have been rapid and impressive, notably with respect to new materials for solar cells.[1]
Replacing lead with tin has had some success, tin-based perovskite photovoltaics still struggle with substantially lower Power conversion efficiencies (PCEs) as well as higher instability and faster degradation, notably owing to the presence of tin vacancies which are formed.[10−13]
Summary
Lead-free silver−bismuth semiconductors have become increasingly popular materials for optoelectronic applications, building upon the success of lead halide perovskites.
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