Wu, LuyanHu, ShuaifengYang, FengLi, GuixiangWang, JunkeZuo, WeiweiJeronimo-Rendon, Jose J.Turren-Cruz, Silver-HamillSaba, MicheleSaliba, MichaelNazeeruddin, Mohammad KhajaPascual, JorgeLi, MengAbate, Antonio2025-03-032025-03-032025-02-282025-02-1910.1038/s41578-025-00781-7https://infoscience.epfl.ch/handle/20.500.14299/247330WOS:001425272300001Metal-halide perovskite solar cells have achieved power conversion efficiencies comparable to those of silicon photovoltaic (PV) devices, approaching 27% for single-junction devices. The durability of the devices, however, lags far behind their performance. Their practical implementation implies the subjection of the material and devices to temperature cycles of varying intensity, driven by diurnal cycles or geographical characteristics. Thus, it is vital to develop devices that are resilient to temperature cycling. This Perspective analyses the behaviour of perovskite devices under temperature cycling. We discuss the crystallographic structural evolution of the perovskite layer, reactions and/or interactions among stacked layers, PV properties and photocatalysed thermal reactions. We highlight effective strategies for improving stability under temperature cycling, such as enhancing material crystallinity or relieving interlayer thermal stress using buffer layers. Additionally, we outline existing standards and protocols for temperature cycling testing and we propose a unified approach that could facilitate valuable cross-study comparisons among scientific and industrial research laboratories. Finally, we share our outlook on strategies to develop perovskite PV devices with exceptional real-world operating stability.EnglishSOLAR-CELLSTHERMAL-STABILITYDAMP HEATPERFORMANCEEFFICIENTDEGRADATIONBEHAVIORDESIGNPHASEHYSTERESISScience & TechnologyTechnologytext::journal::journal article::review article