Litcius/Paper detail

Atomic-Scale Defect Reconfiguration via Thermally Induced Structural Ordering for High-Efficiency Sb<sub>2</sub>Se<sub>3</sub> Solar Cells

Yaozhen Li, Ke Qu, Ruihao Jiang, Haonan Wang, Xiaoyu Zhao, Zhenzhong Yang, Bobo Tian, Jiahua Tao, Junhao Chu, Chun‐Gang Duan

2025ACS Nano21 citationsDOI

Abstract

The photovoltaic performance of antimony triselenide (Sb 2 Se 3 ) thin-film solar cells is fundamentally limited by deep-level defects originating from structural disorder, which severely limit carrier lifetimes. Herein, we propose a thermodynamically driven disorder-to-order transition pathway in Sb 2 Se 3 thin films, enabled by a solution-processable MgCl 2 treatment that facilitates atomic-scale defect passivation across the surface, bulk, and bottom regions. First-principles calculations reveal that Mg 2+ and Cl – ions preferentially occupy Sb and Se vacancies, respectively, thereby modulating vacancy concentrations and blocking atomic migration pathways, which effectively reduces the concentration of pre-existing antisite defects. In parallel, the in situ formation of metastable intermediates ( e.g., MgSe –, MgSe 2 –, and Se 37 Cl – ) acts as a kinetic accelerator for microstructural reconstruction, driving the transformation of disordered nanograins into highly oriented, micron-scale single crystals. This synergistic ionic and structural reconfiguration leads to a 10-fold reduction in trap density and extends photocarrier lifetimes from 0.08–2.6 to 2.7–17 μs, substantially mitigating nonradiative recombination. Consequently, vapor-transport-deposited Sb 2 Se 3 solar cells achieve a certified efficiency of 9.31%, establishing a benchmark. This work provides a mechanistic framework that integrates ionic defect chemistry with lattice ordering, offering a generalizable pathway for enabling low-dimensional photovoltaics.

Topics & Concepts

Materials scienceVacancy defectPhotovoltaicsMetastabilityPassivationChemical physicsIonic bondingCrystallographic defectIonPhotovoltaic systemOptoelectronicsDensity functional theoryNanotechnologyCopper indium gallium selenide solar cellsLattice (music)AntimonyWork (physics)Wide-bandgap semiconductorLow-energy electron microscopySolar cellCharge carrierControl reconfigurationCarrier lifetimeFrenkel defectThin filmKinetic energySemiconductor materials and devicesSemiconductor materials and interfacesPhase-change materials and chalcogenides
Atomic-Scale Defect Reconfiguration via Thermally Induced Structural Ordering for High-Efficiency Sb<sub>2</sub>Se<sub>3</sub> Solar Cells | Litcius