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Not all Australian communities are equally protected by consumer electricity retail regulations, with remote and Indigenous communities more likely to be underserved on multiple fronts. Communities in regions potentially critical to energy transition are often underserved by regulations that would otherwise ensure their own energy needs, hindering progress toward a just transition.
Metal–organic frameworks (MOFs) are porous materials that may find application in numerous energy settings, such as carbon capture and hydrogen-storage technologies. Here, the authors review predictive computational design and discovery of MOFs for separation and storage of energy-relevant gases.
The emissions impact of the time-matching requirement between grid-connected electrolytic hydrogen production and contracted renewables has been the focus of a vigorous policy debate. Energy system model-based analysis of grid-connected hydrogen production demonstrates that emissions impacts under any time-matching requirement are highly sensitive to the definition of additionality and region-specific policies.
The operational stability of perovskite solar cells is often tested in the laboratory environment but its correlation to real-world operation is still unclear. New research shows that the outdoor ageing behaviour of the devices can be modelled with temperature-dependent degradation rates from laboratory stability tests that apply both heat and light stressors.
Bipolar membranes are emerging as an enabling component in numerous energy-relevant electrochemical devices, but a greater understanding of how they operate in complex electrolytes is needed. Research now reveals that ionic species in mixed-ion electrolytes can block the heart of the membrane, the bipolar junction, hampering its performance.
Payments awarded for renewables are sometimes labelled as subsidies, suggesting support for uneconomic activity. This Perspective argues that the primary role of contracts for difference is risk management by creating a market for electricity supply at stable long-term prices.
An interlayer of aluminium oxide with fixed charges is shown to boost perovskite solar cell performance. The open-circuit voltage is increased by 60 meV, and there is no significant efficiency drop after 2,000 hours under one sun illumination at 85 °C.
The mechanical reliability of perovskite solar cells is a key hurdle that needs to be addressed to commercialize the technology. Dai and Padture discuss the driving stress, mechanical properties and mechanical failures relevant to these devices and how they should be characterized.
Nickel-rich layered cathode materials deliver high energy density but suffer from rapid capacity fading owing to various side reactions at the cathode–electrolyte interface. A proposed near-surface modification of nickel-rich cathode materials increases their cycling stability, enabling the realization of high-energy-density and durability requirements for practical application.
A high-quality tunnelling-recombination layer composed of a boron- and phosphorus-doped polycrystalline silicon (poly-Si) stack is obtained by suppressing dopant interdiffusion. Strong adsorption of the hole-transport layer on the poly-Si substrate enables efficient charge-carrier transport and extraction, enabling the realization of a perovskite/tunnel oxide passivating contact tandem solar cell with 29.2% efficiency.
The diverse structures of energy system models result in disparities in computed energy and climate outcomes. Through a systematic quantification of five diagnostic indicators, new research offers a comprehensive ‘energy model fingerprint’ that will enable better contextualization and comparison of models in climate mitigation studies.
As the climate gets more extreme, buildings need to dramatically reduce energy use for heating and cooling. A new model reproduces the relationship between local climate and hourly building energy use, allowing us to reliably quantify the impact of modified indoor or outdoor climatic conditions such as thermostat adjustment or climate change.
The electrochemical CO2 reduction reaction can produce carbon-based fuels; however, the design of more efficient catalysts has proved challenging. A tandem electrocatalyst comprising SnS2 nanosheets and Sn single atoms bound to three oxygen atoms on a carbon support is shown to exhibit high catalytic performance for CO2 reduction to ethanol, including high selectivity.
The long-term operational stability of perovskite photovoltaics is critical to their successful real-world deployment. New research shows that ammonium cations with a high acid-dissociation constant can inhibit degradation reactions and impart excellent long-term stability in solar cells operating at high temperatures.
Electrochemical methods are emerging as potential ways to electrify the production of ammonia (NH3). Now, researchers have discovered a copper–tin electrocatalyst that can efficiently and selectively achieve high production rates of ammonia from nitric oxide (NO) feedstocks, marking a key step forward in decarbonizing ammonia synthesis.
Irreversible structural transitions and disorder in electrodes during battery operation can cause electrochemical performance to deteriorate. Now, an innovative design that turns an irreversible phase transition into a partially disordered phase is shown to be effective in improving disordered rocksalt materials.
Solid electrolytes may enable a step-change in battery performance, but their brittleness often complicates their use. Now, a new inorganic electrolyte has been developed: it is a glassy material that offers viscoelasticity as well as good ionic conductivity.
As the deployment of variable renewable energy sources may lead to greater cross-border electricity exchange, energy scholars have generally presumed the emergence of cooperative multi-state grid communities. This Perspective uses International Relations theory to explore this assumption.
Lithium-ion battery manufacturing is energy-intensive, raising concerns about energy consumption and greenhouse gas emissions amid surging global demand. New research reveals that battery manufacturing will be more energy-efficient in future because technological advances and economies of scale will counteract the projected rise in future energy demand.
Offshore wind energy could have an important role in decarbonizing regional power systems in the USA. By modelling a range of scenarios, power system uncertainties related to policy, technology costs, transmission, and siting are assessed to understand how they influence the deployment of offshore wind.
