perovskite solar cells underwent repetitive cooling to minus 150 degrees Celsius followed by heating up to plus 150 degrees Celsius. The study focused on the transformations in the microstructure of the perovskite layer and its interactions with adjacent layers throughout these cycles. Credit: Li Guixiang” width=”800″ height=”449″/>
Enhancing Durability in Perovskite Solar Cells Through Thermal Stress Management
Perovskite solar cells are lauded for their remarkable efficiency and economical production processes. Nevertheless, their long-term stability under actual environmental conditions remains a significant challenge. A collaborative research effort spearheaded by Professor Antonio Abate has recently provided insights into this matter through a comprehensive article published in Nature Reviews Materials.
The Impact of Thermal Cycling on Solar Cell Performance
The study investigated how various thermal cycles affected both microstructural characteristics and layer interactions within perovskite solar cells. The research findings indicate that thermal stress plays a crucial role in the degradation of metal-halide perovskites, leading to essential strategies aimed at enhancing their longevity.
Metal-halide perovskites stand out within a broader category of materials known for their semiconducting properties suited for energy conversion used in solar technologies; some formulations boast impressive efficiencies reaching up to 27%. Manufacturing thin-film counterparts utilizes minimal material and energy resources, promising more affordable solar options. However, real-world applications necessitate that these modules remain largely effective over spans of two to three decades—a domain where further advancements are imperative for perovskites.
Navigating Real-World Challenges
“Solar modules face various weather influences year-round,” remarks Abate. While encapsulation efficiently shields these power generators from moisture and atmospheric components, they still encounter considerable temperature fluctuations both diurnally and seasonally. Depending on geographical variations, interior temperatures can vary dramatically—from as low as minus 40 degrees Celsius to highs around plus 100 degrees Celsius (particularly evident in arid environments).
To accurately replicate these conditions, the examined perovskite solar cells were subjected to extreme cycles ranging between minus 150 degrees Celsius and plus 150 degrees Celsius repeatedly. Dr. Guixiang Li conducted an analysis on how these temperature transitions influenced changes within the microstructure of the perovskite layer while also assessing neighboring layers’ responses.
Understanding Thermal Stress Effects
The interplay between internal film stresses and inter-layer pressures critically affects overall cell performance. These rapid temperature transitions induce considerable thermal stress both within each individual layer as well as across distinct material interfaces: “For optimal performance in a single cell configuration comprised of multiple disparate materials; intimacy at contact points is essential,” explains Abate.
This challenge stems from differing thermal expansion characteristics inherent among layered materials—organic compounds tend generally to contract upon heating whereas inorganic substances expand accordingly—all leading to deteriorating contact quality with each cycle alongside potential phase shifts or elemental diffusion observed at proximity boundaries.
A Pathway Toward Improved Stability
The findings have birthed actionable strategies targeting enhanced resilience against thermal stress effects among metal-halide compositions used within photovoltaic constructs: “Understanding thermal dynamics is pivotal,” notes Abate who emphasizes refining crystalline qualities while also employing effective buffer layers as necessary approaches moving forward.
The team advocates standardization among testing methodologies dedicated towards evaluating stability via temperature cycling patterns ensuring consistency across varied studies enhances validity when comparing results globally.
Further Insights & Research Directions
This critical dialogue has been captured comprehensively by Luyan Wu et al., detailing pathways toward improved durability outcomes specifically tailored towards halide-perovkskite photovoltaics amidst rigorous climatic testing scenarios improved knowledge accumulation will help address pertinent longevity concerns poised before this technology’s wide adoption internationally.
More information can be found here:
Luyan Wu et al., Resilience pathways for halide peroskites photovoltaics under temperature cycling, Nature Reviews Materials (2025). DOI: 10.1038/s41578-025-00781-7.
Provided by Helmholtz Association of German Research Centres
