Strain Engineering for Tailored Carrier Transport and Thermoelectric Performance in Mixed Halide Perovskites CsPb(I_1–xBr_x)₃

Abstract: Strain engineering of metal halide perovskites shows promise for better stability and device performance, but the impact on thermoelectric performance remains elusive. We demonstrate that the electronic structures and carrier transport properties in halide perovskites CsPb­(I1–x Br x )3 can be tailored synergetically through the practical biaxial strain-engineering strategies. For the pure halide perovskite CsPbI3, the lattice geometry and electronic structures are basically retained under strains (from −6 to … Show more

“…62,63 In particular, because of the accelerated ion migration under the action of an electric field, mixed halogen perovskites (CsPb-(I 1−x Br x ) 3 ) are prone to generate halide phases segregation. 64,65 Hence, developing pure-red LED devices based on mixed-halide perovskites is still a big challenge.…”

“…Ion migration induces many vacancies and interstitial defects, destroying the perovskite lattice and deteriorating the performance of the LED devices. Moreover, ion migration is an intractable issue that cannot be resolved by eliminating external stimuli such as moisture and heat. , In particular, because of the accelerated ion migration under the action of an electric field, mixed halogen perovskites (CsPb­(I 1– x Br x ) 3 ) are prone to generate halide phases segregation. , Hence, developing pure-red LED devices based on mixed-halide perovskites is still a big challenge.…”

Recent Progress in the Stability of Red-Emissive Perovskite Nanocrystals for Light-Emitting Diodes

“…62,63 In particular, because of the accelerated ion migration under the action of an electric field, mixed halogen perovskites (CsPb-(I 1−x Br x ) 3 ) are prone to generate halide phases segregation. 64,65 Hence, developing pure-red LED devices based on mixed-halide perovskites is still a big challenge.…”

“…Ion migration induces many vacancies and interstitial defects, destroying the perovskite lattice and deteriorating the performance of the LED devices. Moreover, ion migration is an intractable issue that cannot be resolved by eliminating external stimuli such as moisture and heat. , In particular, because of the accelerated ion migration under the action of an electric field, mixed halogen perovskites (CsPb­(I 1– x Br x ) 3 ) are prone to generate halide phases segregation. , Hence, developing pure-red LED devices based on mixed-halide perovskites is still a big challenge.…”

Recent Progress in the Stability of Red-Emissive Perovskite Nanocrystals for Light-Emitting Diodes

“…2 shows the maximum ZT achieved for bulk thermoelectric materials over the past six years as a function of temperature. 33–234…”

Recent advances in designing thermoelectric materials

“…Their theoretical results show that the electronic structure of CsPbI 3 perovskite exhibits abrupt changes at −8% strain, which will affect the carrier transport. [ 27 ] In addition, Ma et al performed DFT calculations with a theoretical model of biaxial strain, in conjunction with the Williamson–Hall method, to demonstrate that the enhanced phase stability of α‐CsPbI 3 distributed in vertically aligned nanopores is owing to the reduced surface formation energy caused by compressive strain. [ 28 ] Considering that in‐plane tensile strain is prevalent in perovskite films prepared by conventional solution methods, the effect of biaxial strain needs to be studied theoretically, which will guide the relaxation of residual strain to obtain the most superior films.…”

Strain Relaxation for Perovskite Lattice Reconfiguration