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Capacity is often used to evaluate and monitor battery state and health. Now, lithium inventory transactions can be accurately tracked at the electrode–electrolyte interface to improve battery performance and reliability.
Wide-bandgap perovskite solar cells suffer from phase segregation. Zhang et al. show that thiocyanate ions overcome the issue by occupying iodide vacancies while regulating crystallization, enabling perovskite/organic tandem cells with 25.06% efficiency.
Wide band gap perovskite solar cells suffer from halide segregation, which hampers their use in tandem solar cells. Now, researchers develop an additive with redox and defect passivating capabilities to suppress halide migration, enabling perovskite–organic tandems with over 25% efficiency.
Understating degradation pathways is critical to the development of perovskite photovoltaics. Thiesbrummel et al. show that internal electric field screening induced by ion migration is a dominant contributor to the operational performance loss of perovskite solar cells.
A new study from Moritz Wussow and colleagues assesses solar deployment equity across residential and non-residential sectors and discusses pathways for policy action to promote non-residential solar in disadvantaged communities.
Using a hybrid fixture, application of an appropriate external pressure on Li-metal pouch cells with a liquid electrolyte considerably reduces cell swelling. Mapping of the pressure distribution across the cell surface provides insight into the electroplating process that could inform strategies to overcome uneven Li plating on the Li-metal surface.
During extreme storms, the failure of a small fraction of transmission lines can trigger a cascade of outages in a power grid. Going beyond static approaches, it is now demonstrated that resolving the spatio-temporal interactions between the storm and the power grid is key to identifying these critical lines.
Cell swelling poses a considerable obstacle in the development of lithium-metal batteries. Here the authors report the use of a hybrid pressure-application fixture to substantially reduce swelling, analyse the pressure distribution across the cell surface and provide insights for further battery stabilization.
Recycling spent batteries is crucial for a circular battery economy, yet knowledge of solid-state battery (SSB) recycling lags behind that of lithium-ion batteries. This study evaluates SSB recycling techniques, emphasizing the need for specific, energy-efficient methods tailored to distinct electrolytes.
Factors such as wealth might be expected to affect the transition to clean cooking, specifically the transition choices of uptake, primary use, and exclusive use of liquefied petroleum gas. Data from Ghana’s largest household energy survey show, however, that eleven out of thirteen factors considered do not have a significant or consistent role across these transition choices.
Ion solvation at solid–electrolyte interfaces is crucial in various components of energy conversion technologies, including water splitting electrocatalysts and bipolar membranes, but is poorly understood. Here the authors study ion solvation kinetics in these systems, highlighting the key role of interfacial capacitance in determining behaviour.
Copper catalysts hold promise for producing multi-carbon chemicals through electrochemical CO2 reduction, but improving performance is challenging due to the limited tunability of the copper surface. Now, research uses organic functionalization to modify the surface oxidation state of copper, yielding improved energy efficiency for ethylene production.