posted on 2023-11-29, 07:43authored bySa’ar Shor Peled, Kumaraswamy Miriyala, Alexander Rashkovskiy, Ron Fishov, Vitali Gelberg, Joshua Pelleg, Daniel A. Grave
Silver thin film mirrors are attractive candidates for
use as specular
back reflectors to enhance broadband light absorption via strong optical
interference in ultrathin film semiconductor photoabsorbers. However,
deposition of metal-oxide absorbers often requires exposure to high
temperature in an oxygen atmosphere, conditions that cause thermal
etching and degrade the specular reflectance of silver films. Here,
we overcome this challenge and demonstrate that epitaxial growth of
silver mitigates thermal etching under the high-temperature oxygen-containing
environments that cause polycrystalline films to degrade. The degree
of thermal etching resistance is related to the epitaxial film structure,
where high-quality films completely prevent thermal etching, allowing
for direct deposition of metal-oxide thin film photoabsorbers at elevated
temperatures without any degradation of the optical properties of
the silver layer. As a proof of concept for device applications, a
metal-oxide photoanode for photoelectrochemical water splitting is
fabricated by directly growing epitaxial SnO2 and Ti-doped
α-Fe2O3 (hematite) thin films onto stabilized
silver reflectors by pulsed laser deposition. The photoanode displays
enhanced broadband light absorption due to strong interference effects
enabled by the highly reflective silver film and demonstrates stable
operation in a photoelectrochemical cell under conditions of water
photo-oxidation in alkaline electrolyte.