Dr Severin Habisreutinger

Assessment of soil impacts from lead release by lead-halide perovskite solar cells based on outdoor leaching tests

EES Solar Royal Society of Chemistry (2025)

Authors:

Anika Sidler, Felix Schmidt, Bastien Vallat, Fionnuala Grifoni, Severin N Habisreutinger, Riikka Suhonen, Henry J Snaith, Andreas Schäffer, Markus Lenz

Abstract:

Perovskite solar cells represent a promising technology in the photovoltaic industry due to their high power conversion efficiency, potential for cost-effective manufacturing and versatile applications. The most stable and efficient perovskites to date rely on lead (Pb), raising concerns about leaching into the environment; however Pb release so far has only been quantified under laboratory conditions, and no field-based assessment under real outdoor expsosure has yet evaluated this risk. The present study quantified Pb leaching from various metal-halide perovskite compositions, device stacks and encapsulation approaches in a rooftop installation for up to 9 months. Pb leaching was low across all tested configurations, even in intentionally damaged materials. Glass–glass encapsulated tandem devices shattered by hail and plastic-encapsulated samples damaged by 100 µm pinholes released only 0.07% ± 0.01% and 0.15% ± 0.14% of their initial Pb, respectively, likely due to the slow diffusion of Pb cations in water. The highest leaching (4.81% ± 0.02%) occurred in unlaminated laboratory devices, demonstrating the importance of proper lamination. A self-developed freeware web tool was used to calculate predicted soil concentrations and evaluate potential impacts. Even for unlaminated devices, concentrations would only slightly exceed natural background levels (5.6 mg kg−1 increase), with negligible effects on soil fertility. A hypothetical worst-case scenario assuming a 1000 nm thick perovskite layer and complete Pb leaching onto a narrow strip of soil predicted a negative impact on soil fertility; however remediation would still not be required under Swiss environmental regulations. Overall, current industry-standard encapsulation limits Pb leaching to levels that almost completely mitigate negative impacts on soil health.

Measuring metal halide perovskite single cell degradation consistent with module-based conditions

Sustainable Energy & Fuels Royal Society of Chemistry (RSC) 8:3 (2024) 546-553

Authors:

Robert Tirawat, Amy E Louks, Mengjin Yang, Severin N Habisreutinger, Jao van de Lagemaat, Soňa Uličná, Ross A Kerner, Kai Zhu, Laura T Schelhas, Axel F Palmstrom, Joseph J Berry

Nanocrystal‐Enabled Perovskite Heterojunctions in Photovoltaic Applications and Beyond

Advanced Energy Materials Wiley 13:22 (2023)

Authors:

Brian M Wieliczka, Severin N Habisreutinger, Kelly Schutt, Jeffrey L Blackburn, Joseph M Luther

Analytical Evaluation of Lead Iodide Precursor Impurities Affecting Halide Perovskite Device Performance

ACS Applied Energy Materials American Chemical Society (ACS) 6:1 (2023) 295-301

Authors:

Ross A Kerner, Earl D Christensen, Steven P Harvey, Jonah Messinger, Severin N Habisreutinger, Fei Zhang, Giles E Eperon, Laura T Schelhas, Kai Zhu, Joseph J Berry, David T Moore

Utilizing nonpolar organic solvents for the deposition of metal-halide perovskite films and the realization of organic semiconductor/perovskite composite photovoltaics

ACS Energy Letters American Chemical Society 7:2022 (2022) 1246-1254

Authors:

Nakita K Noel, Bernard Wenger, Severin N Habisreutinger, Henry J Snaith

Abstract:

Having captivated the research community with simple fabrication processes and staggering device efficiencies, perovskite-based optoelectronics are already on the way to commercialization. However, one potential obstacle to this commercialization is the almost exclusive use of toxic, highly coordinating, high boiling point solvents to make perovskite precursor inks. Herein, we demonstrate that nonpolar organic solvents, such as toluene, can be combined with butylamine to form an effective solvent for alkylammonium-based perovskites. Beyond providing broader solvent choice, our finding opens the possibility of blending perovskite inks with a wide range of previously incompatible materials, such as organic molecules, polymers, nanocrystals, and structure-directing agents. As a demonstration, using this solvent, we blend the perovskite ink with 6,6-phenyl-C-61-butyric acid methyl ester and show improved perovskite crystallization and device efficiencies. This processing route may enable a myriad of new possibilities for tuning the active layers in efficient photovoltaics, light-emitting diodes, and other semiconductor devices.