Solar Fuel Production from Hydrogen Sulfide: An Upstream Energy Perspective

Abstract: Hydrogen sulfide is readily available in vast quantities in the subsurface as a byproduct of industrial processes. Hydrogen evolution from H2S can transform this highly toxic gas into a source of green fuel. Compared to water splitting, H2S dissociation is thermodynamically more favorable. However, feasible industrial‐scale catalytic technologies are not developed yet. The recovery of valuable chemicals using carbon‐neutral photocatalytic processes can capitalize on abundant solar irradiation and advanced semi… Show more

“…, 33 kJ mol −1 . 4 H 2 S gas is a toxic byproduct emitted in large quantities from both natural sources and industrial processes, and it may increase precipitously in the future. Growing concerns about the environment and resource utilisation have pushed research into novel technologies to convert H 2 S to S and H 2 as green fuels using solar energy.…”

A cubic Sm@CdS Q-dot glass as a photocatalyst for solar H₂ generation

“…, 33 kJ mol −1 . 4 H 2 S gas is a toxic byproduct emitted in large quantities from both natural sources and industrial processes, and it may increase precipitously in the future. Growing concerns about the environment and resource utilisation have pushed research into novel technologies to convert H 2 S to S and H 2 as green fuels using solar energy.…”

A cubic Sm@CdS Q-dot glass as a photocatalyst for solar H₂ generation

“…1–4 One of the most dangerous and toxic pollutants is H 2 S gas, generated on a large scale during various natural and industrial processes. 5–7 Facing the H 2 S issue, the existing routes to solve the problem are the use of adsorbents, thermal decomposition, electrochemical and photo-splitting, and burning in an oxygen atmosphere (Claus process) with the aim of H 2 S elimination and production of hydrogen, sulfur, or other value-added materials. 8–11 Among these methods, the utilization of photons (sunlight) and semiconducting photocatalyst materials is an easy and economical way to convert this harmful pollutant into hydrogen fuel, and has attracted the attention of many researchers in recent years.…”

A novel magnetic HS⁻-adsorptive nanocomposite photocatalyst (rGO/CoMn₂O₄–MgFe₂O₄) for hydrogen fuel production using H₂S feed

High‐Throughput Computational Screening of Metal Sulfides for the Chemical Looping Elemental Decomposition of H₂S