# Reorientation‐Driven Degradation in Oriented Perovskite Films: Shifting Facet Engineering to Thermodynamic Stability

**Authors:** Xiaojing Ci, Xiongzhuo Jiang, Guangjiu Pan, Kun Sun, Altantulga Buyan‐Arivjikh, Zerui Li, Lixing Li, Thomas Baier, Matthias Schwartzkopf, Sarathlal Koyiloth Vayalil, Peter Müller‐Buschbaum

PMC · DOI: 10.1002/smll.202513081 · 2026-01-17

## TL;DR

Highly oriented perovskite films in solar cells are less thermally stable, leading to faster degradation and lower efficiency over time.

## Contribution

The study reveals that strong crystallographic orientation in perovskite films compromises thermal stability due to microstrain accumulation.

## Key findings

- Highly oriented perovskite films retain only 73% of initial efficiency after thermal aging, compared to 89% in less-oriented films.
- Thermal stress causes reorientation and lattice distortion, leading to microstrain and accelerated degradation.
- Metastability is an intrinsic consequence of high crystallographic order, necessitating thermodynamic equilibrium-based engineering.

## Abstract

Hybrid perovskite solar cells (PSCs) suffer from underexplored links between crystallographic orientation and thermal stability, especially in narrow‐bandgap devices. We fabricate highly oriented mixed Sn‐Pb perovskite films via an additive‐free two‐step method. Accelerated aging studies at 120°C reveal that high orientation paradoxically compromises stability, and PSCs built from highly oriented perovskite films retain only 73% of their initial power conversion efficiency (PCE), compared to 89% PCE in less‐oriented devices. Operando grazing‐incidence wide‐angle X‐ray scattering of the PSCs shows that thermal stress induces significant reorientation and lattice distortion in the oriented crystallites, accumulating pronounced microstrain that accelerates the PSC degradation. Structural analyses confirm progressive crystallographic transitions, including grain reconfiguration, shifts toward isotropy, and systematic diffraction migrations. Critically, we demonstrate that metastability is an intrinsic consequence of high crystallographic order, which is why the very high alignment strategies that enhance performance induce thermodynamic vulnerability. This necessitates redesigning crystal engineering priorities where suppressing instability requires engineering thermodynamic equilibrium states over maximizing alignment for stable perovskite photovoltaics.

The role of crystallographic orientation in the thermal stability of narrow‐bandgap perovskite solar cells remains largely underexplored. In Sn–Pb mixed perovskite films, strong orientation can inherently compromise stability under prolonged thermal stress, triggering reorientation‐induced degradation through microstrain accumulation. These findings underscore the importance of prioritizing thermodynamic‐equilibrium‐based engineering over maximizing crystal alignment alone to achieve stable photovoltaic performance.

## Full-text entities

- **Chemicals:** Pb (MESH:D007854), Sn (MESH:D014001), Perovskite (MESH:C059910)

## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12965117/full.md

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Source: https://tomesphere.com/paper/PMC12965117