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CdTe solar cells have relied for decades on copper, which creates limited hole density, stability issues and a ceiling for voltage and efficiency. Now, Metzger et al. demonstrate As-doped Cu-free polycrystalline CdTe cells with enhanced hole density and dopant stability, achieving 20.8% efficiency.
Ultrathin solar cells having thicknesses below 1 µm can still reach efficiencies comparable to their thicker counterparts, but require less material to manufacture. By exploiting light-trapping nanostructures, Chen and colleagues achieve GaAs solar cells with 20% efficiency at just 205 nm thicknesses.
Many different molecules can form during photocatalytic reduction of CO2, so identifying catalyst structure–product selectivity relationships is vital. Here, the authors find that sulfur-deficient CuIn5S8 is highly selective to CH4 and suggest that the presence of Cu–In binding sites is key to this behaviour.
Extensive efforts have recently been geared towards developing all-solid-state batteries largely because of their potential to enable high-energy-density Li anodes. Here, the authors report a high-performance lithium pouch cell with no excess lithium, enabled by just a dual-salt liquid electrolyte.
Adsorbing natural gas in porous materials is a potential storage alternative to conventional approaches based on liquefaction or compression, but higher capacities are required for commercial viability. Here, the authors employ porous covalent organic polymers that are flexible but robust, leading to high storage capacities and cyclability.
Improvements in building envelope performance and onsite power generation are key to enabling zero-energy buildings. Here, Svetozarevic et al. present an adaptive solar facade driven by soft robotic solar trackers that allow both the modulation of daylight penetration and energy generation.
Air pollution has significant effects on human health and well-being, but also on the ability of solar panels to produce energy. Sweerts et al. find that the loss in potential solar electricity generation in China, due to increased pollution from industrialization from the 1960s onwards, could amount to 14 TWh in 2016 and 51–74 TWh by 2030.
The performance of Li-ion batteries deteriorates at elevated temperatures due to increased activity of electrode materials and parasitic reactions. Here Yi Cui and colleagues report much-improved battery cyclability at 60 °C and use cryo-electron microscopy to shed light on the origin of the phenomenon.
Voltage hysteresis plagues several important families of battery electrodes, yet our understanding of its thermochemical properties remains poor. Here, the authors use isothermal calorimetry to measure the thermal effects of voltage hysteresis in a lithium-rich layered cathode and propose a mechanism for oxygen redox.
Lead leakage from damaged perovskite solar cells poses a challenge to the deployment of such technology. Here, Jiang, Qiu and co-workers quantify lead leakage caused by a simulated hail impact under a number of weather conditions and show that self-healing encapsulations can effectively reduce it.
While thicker battery electrodes are in high demand to maximize energy density, mechanical instability is a major hurdle in their fabrication. Here the authors report that segregated carbon nanotube networks enable thick, high-capacity electrodes for a range of materials including Si and NMC.
LiCoO2 is a widely used cathode material in Li-ion batteries for applications such as portable electronics. Here, the authors report multiple-element doping to enable stable cycling of LiCoO2 at high voltages that are not yet accessible with commercial Li-ion batteries.
Real-world conditions under which solar cells operate can be different from standard testing conditions. Tress et al. investigate the effects of temperature and irradiation on the performance of a perovskite cell and a reference silicon cell, reproducing real weather conditions in the laboratory.
Biomass can be used to scavenge photogenerated holes in photocatalytic hydrogen production, but the oxidized molecules that form are not always useful products. Here, the authors use Ru-ZnIn2S4 to photocatalyse the dehydrogenative C−C coupling of lignocellulose-derived methylfurans, forming both hydrogen and diesel fuel precursors.
Some of the best electrocatalysts for the oxygen evolution reaction in alkaline electrolysers are based on oxides of nickel and iron. Here, the authors demonstrate that the water oxidation performance of such catalysts can be enhanced by application of a magnetic field from a permanent magnet.
Isolating metal atoms on supports is becoming an increasingly studied approach to design water splitting electrocatalysts. Here, the authors prepare a hydrogen evolution catalyst comprising atomically dispersed Pt atoms on curved carbon supports, which outperform similar catalysts where the support is flat.
Manufacturing high-performing solid electrolytes at low processing temperature requires improved techniques. Here Jennifer Rupp and colleagues report a ceramic processing strategy, using Li3N multilayers as a lithium reservoir for the formation of lithium–garnet films, significantly reducing the operating temperature while maintaining the ionic conductivity.
Much has been said about the high-energy, long-lasting potential of Li metal batteries, and yet little has been demonstrated at the cell scale. Here, Jun Liu and colleagues demonstrate a Li metal pouch cell with a 300 Wh kg−1 energy density and a 200-cycle lifetime.
Selenium in cadmium telluride solar cells is known to allow bandgap engineering, thus enabling highly efficient devices. Here, Fiducia et al. show that selenium also plays a role in passivating defects in the absorber layer.
Intensive research efforts are underway to enable applications of layered lithium transition metal oxides in batteries. Here the authors report an oxidative chemical vapour deposition technique to conformally coat both the primary and the secondary particles of these oxides to unleash potential applications.