Transparent Conductive Encapsulants for Photoelectrochemical Applications

Abstract: Utilizing sunlight to directly perform photoelectrochemical reactions is a promising route to renewable, net carbon‐neutral fuels. However, a common problem with solar fuel production is semiconductor degradation in aqueous environments. An ideal protection layer should (1) prevent solution from reaching the semiconductor, (2) maintain charge transfer to and from solution, and (3) be transparent to light above the semiconductor band gap. While there have been substantial advances toward layers that meet these … Show more

“…10,18–20 The introduction of protective layers ( e.g. TiO 2 , MoS 2 , sacrificial ions, and polymer films) 5,11,21–27 has greatly extended the illuminated operation of photoelectrodes. However, under real outdoor operating conditions, a semiconductor photoabsorber operating as a photoelectrode needs to be stable under day/night (diurnal) lighting conditions.…”

Utilizing three-terminal, interdigitated back contact Si solar cells as a platform to study the durability of photoelectrodes for solar fuel production

“…10,18–20 The introduction of protective layers ( e.g. TiO 2 , MoS 2 , sacrificial ions, and polymer films) 5,11,21–27 has greatly extended the illuminated operation of photoelectrodes. However, under real outdoor operating conditions, a semiconductor photoabsorber operating as a photoelectrode needs to be stable under day/night (diurnal) lighting conditions.…”

Utilizing three-terminal, interdigitated back contact Si solar cells as a platform to study the durability of photoelectrodes for solar fuel production

Realization of a Photoelectrochemical Cascade for the Generation of Methanol: A Liquid Solar Fuel