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Li metal batteries offer much hope for the future of high-energy storage systems. Albertus et al. survey the current status of research and commercial efforts, and discuss key metrics and measurements as well as cost issues in enabling high-performing lithium metal electrodes.
Understanding interfacial charge transfer in water-splitting photoelectrodes is complicated by the delicate interplay between catalyst and light absorber. Now, an approach based on atomic force microscopy is exploited to measure the surface electrochemical potential of nanostructured catalyst-coated electrodes in operando.
Photoelectrodes used to split water, driven by solar energy, often suffer from a lack of stability. Here the authors demonstrate that a V5+-saturated electrolyte can be used to inhibit photooxidation-coupled dissolution of a BiVO4 photoanode, suppressing photocorrosion and allowing stable photocurrent generation over hundreds of hours.
Photoelectrochemical water splitting to produce H2 is dependent on the electrochemical potentials between photoelectrodes and the electrolyte, which are difficult to measure. Here the authors use an electrochemical atomic force microscope technique to sense the potential of catalyst-coated electrode surfaces in operando.
It is challenging to unlock anionic redox activity, accompanied by full utilization of available cationic redox process, to boost capacity of battery cathodes. Now, material design by tuning the metal–oxygen interaction is shown to be a promising solution.
Hydropower represents about 20% of sub-Saharan electricity, and expansion is underway. Rainfall varies year-to-year in geographical clusters, increasing the risk of climate-related electricity supply disruption in dry years.
It is challenging to exploit anionic redox activity to boost performance of battery electrodes, especially for anti-fluorite structures. Here the authors report simultaneous anionic and cationic redox in Li5FeO4, which enables its high capacity and eliminates the undesired oxygen gas release.
CO2 is often found alongside CH4 in natural gas wells; therefore, separation of the gases is an important industrial process. Jalilov et al. demonstrate that the adsorption selectivity for CO2 over CH4 can be significantly enhanced through introduction of water into the pores of a high-surface-area carbon.
Hydropower is critical to eastern and southern Africa but it is at risk from climate variability. Conway et al. examine river basins and rainfall variability to explore potential hydropower disruption for present and planned generation sites, highlighting the risks to supply and their spatial interlinkages.
All energy generation technologies emit greenhouse gases during their life cycle as a result of construction and operation. Pehl et al. integrate life-cycle assessment and energy modelling to analyse the emissions contributions of different technologies across their lifespan in future low-carbon power systems.
Cation engineering has been used to tune the efficiency and stability of perovskite solar cells. Here, Jodlowski et al. introduce guanidinium, a cation slightly larger than previously thought possible, mixed with the traditional methylammonium cation, into the 3D structure, improving device stability.
Anionic redox provides extra capacity for battery electrodes, but it is challenging to realize its full potential. Tarascon and colleagues report a record-high reversible capacity of 3.5 electrons per Ir in a Li3IrO4 phase, and discuss the importance of increasing the ratio of oxygen versus transition metal.
Although nearly all 2 °C scenarios use negative CO2 emission technologies, only relatively small investments are being made in them, and concerns are being raised regarding their large-scale use. If no explicit policy decisions are taken soon, however, their use will simply be forced on us to meet the Paris climate targets.
Understanding individual energy use can inform interventions for energy conservation. A longitudinal qualitative interview study shows that energy use behaviour is not simply a matter of individual choice, but rather is influenced by unique personal circumstances and familial and social relationships, which change over time.
Electricity grids are susceptible to damage from climate-related incidents, which can cause power outages. This study shows that the value of uninterrupted electricity supply across 19 EU nations is related to local temperature, with summer power outages becoming more costly with global warming.