Stoichiometric Engineering of Cs<sub>2</sub>AgBiBr<sub>6</sub> for Photomultiplication-Type Photodetectors
Metikoti Jagadeeswararao, Kyu Min Sim, Sang‐Jun Lee, Mingyun Kang, Sanghyeok An, Geon‐Hee Nam, Hye Ryun Sim, Elham Oleiki, Geunsik Lee, Dae Sung Chung
Abstract
Photomultiplication (PM)-type photodetectors with a high external quantum efficiency (EQE) can be realized through adequately engineered trap states and trap-assisted charge injection. By strategically introducing slightly rich Bi and highly rich Br stoichiometric conditions, efficient trap states are realized for holes in lead-free Cs 1.98 AgBi 1.15 Br 7.9 double perovskite (DP). With the diode structure of ITO/SnO 2 /Cs 1.98 AgBi 1.15 Br 7.9 /poly(3-hexylthiophene) (P3HT)/MoO x /Ag, where SnO 2 and P3HT layers are used as the hole- and electron-blocking layers, respectively, successful realization of the selective hole trap and the resulting band bending/electron injection at the anode interface is demonstrated. As a result, a high EQE of ∼16,000%, responsivity of ∼50 A W –1, and specific detectivity of over 10 12 Jones at −3 V are demonstrated. The origin of the suggested PM mechanism is discussed using photophysical and optoelectronic measurements and theoretical studies. This work ensures the successful demonstration of PM-type photodetectors using lead-free Cs 2 AgBiBr 6 DP through strategic trap engineering.