Hafnium oxide interface stabilization for efficient, photothermally stable perovskite solar cells
Summary
Organic molecular layers at both hole- and electron-selective interfaces are essential for achieving high-efficiency perovskite solar cells, yet their limited photothermal stability hinders long-term device operation. We used atomic layer deposition to deposit hafnium oxide (HfOx) interlayers to stabilize these molecular interfaces under operational stress. At the NiOx/self-assembled monolayer (SAM) interface, a hydroxyl-rich, Lewis-acidic n-HfOx layer (n denotes negative fixed-charge pola
Content
# Hafnium oxide interface stabilization for efficient, photothermally stable perovskite solar cells
*Published: 2026 Feb 26*
Organic molecular layers at both hole- and electron-selective interfaces are
essential for achieving high-efficiency perovskite solar cells, yet their
limited photothermal stability hinders long-term device operation. We used
atomic layer deposition to deposit hafnium oxide (HfOx) interlayers to stabilize
these molecular interfaces under operational stress. At the NiOx/self-assembled
monolayer (SAM) interface, a hydroxyl-rich, Lewis-acidic n-HfOx layer (n denotes
negative fixed-charge polarity) promoted tridentate phosphonic acid coordination
and enhanced SAM retention and thermal durability. At the perovskite/C60
interface, the p-HfOx layer (p denotes positive fixed-charge polarity) anchored
3-fluorophenylethylammonium iodide (3F-PEAI) through Hf⋯F interactions that also
acted as a diffusion barrier against halide- and silver-ion migration. Devices
achieved a power conversion efficiency of 27.1% (26.6% certified) and retained
more than 90% of their initial efficiency for ~5000 hours under 1-sun equivalent
illumination at 85°C in ambient air.
DOI: 10.1126/science.aea3339