Themed collection 3rd International Solar Fuels Conference and International Conference on Artificial Photosynthesis

This review discusses strategies to enhance oxygenic photoautotrophic carbon fixation with a focus on the Calvin–Benson–Bassham cycle.

Visible-light driven CO₂ reduction and utilization systems involving the photoreduction of NAD(P)⁺ or bipyridinium salt (viologen)-based electron mediators and biocatalysts are introduced.

Herein, we review the recent advances and challenges in the field of visible-light-absorbing semiconductor/molecular catalyst photoelectrodes for H₂ and O₂ evolution.

Flash photolysis studies indicate general base catalysis by borate in photoinduced proton-coupled electron transfer from Co₃O₄ nanoparticles to Ru(III)(bpy)₃³⁺.

The instability of perovskite solar cells under oxygen and light stress can be alleviated by choosing a suitable device interlayer and device configuration.

Herein, we report a nano-hybrid photo-system based on abundant elements for H₂ production with visible light.

The photocatalytic activity of a new broad absorbing osmium–platinum photocatalyst is determined by the choice of excitation wavelength.

A new transparent mesoporous IrO_x film consisting of small interconnected nanoparticles has been developed by a simple drop-cast method to provide an efficient electrocatalyst film for water oxidation.

Non-bias production of a bleach aqueous solution was successfully demonstrated using a solar-driven photoelectrochemical cell consisting of a metal-oxide-semiconductor photoanode and Pt-based cathode.

A photoelectrochemical-voltaic cell consisting of Zn_xCd_1−xSe photoanodes generates a photovoltage higher than the thermodynamic onset voltage for water splitting, 1.23 V.

Mitigation of ohmic losses and mass transport limitations enables a large area BiVO₄-based water splitting device with a solar-to-hydrogen efficiency of 2.1%.

Microstructured photoelectrode morphologies can advantageously facilitate integration of optically absorbing electrocatalysts with semiconducting light absorbers.

Dual loading of Rh and Ru-based cocatalysts on TaON photocatalyst significantly improves the efficiency of oxygen evolution in Z-scheme water splitting.

We numerically investigate the conversion of solar energy into chemical energy by integrated photo-electrochemical (IPEC) devices and assess their response to time-dependent changes in the boundary conditions and the material properties.

A transient absorption spectroscopy study is conducted to correlate carrier dynamics with photocatalytic H₂ evolution efficiency in the La/Rh doped SrTiO₃ photocatalyst.

The link between morphology and multi-physical transport was numerically quantified based on the geometry of a photoelectrode obtained by FIB-SEM tomography.

Micro-structured p-Si/TiO₂/NiO_x allows for efficient photoelectrochemical H₂ production from seawater.

Quantitative description of electrolyte impact is established for nanoscale water electrolysis prevalent during photocatalytic overall water splitting.

NiFe oxyhydroxides are prime candidates for efficient alkaline water oxidation; their redox chemistry is tracked by X-ray spectroscopy.

Under basic condition, SiTPyP(O⁻)₂ exerts two-electron oxidation of water to form hydrogen peroxide as the primary product in aqueous acetonitrile, which is initiated through one-electron oxidized process on the electrode with faradaic yield of 84–92%.

Efficient H₂O₂ production on both the Al₂O₃/BiVO₄/WO₃ photoanode and carbon cathode loaded with a biomass-derived cathode without external bias was demonstrated.

Preparation of Bi₄MO₈X with excess BiOX precursors substantially improved their photocatalytic activity for water oxidation by suppressing the formation of surface halogen defects.

The search for ideal semiconductors for photoelectrochemical solar fuel conversion has recently recognized the spinel ferrites as promising candidates due to their optoelectronic tunability together with superb chemical stability.

Configuration of the perovskite solar cell and diagram of the mechanism of preparation of TiO₂ using atomic-layer deposition.

Physical vapour deposition of Mn metal followed by annealing in air is a promising route to prepare MnO_x-anodes for water-oxidation.

Highly crystalline Ni-doped β-FeOOH(Cl) nanorod catalysts for efficient electrochemical water oxidation were successfully synthesized by a one-pot ambient temperature synthesis.