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Population-level analyses and in vitro experiments show that a specific genetic variant of cyclin D3 inhibits the growth of the malaria-causing parasite Plasmodium falciparum in erythrocytes, and suggest that its high frequency in Sardinia was driven by past endemic malaria.

Silicon anodes promise much higher battery capacity but are limited by poor storage life. This work identifies key ageing mechanisms and suggests ways to improve long-term stability.

Organic lasers, known for their colour purity, are emerging as next-generation light emitters. Here, the authors use a self-driving laboratory to discover soluble red-shifted emitters and automate the search for solution-processable laser dyes.

Guided by density functional theory, a commercially viable refractory alloy is developed, which exhibits excellent room-temperature ductility and strength, and high strength at elevated temperatures.

Rice paddies contribute to atmospheric methane (CH₄) levels. Here the authors show that increasing levels of the rice plant hormone PSY can reduce CH₄ emissions by over 50% via alteration of microbial H₂ cycling in the rhizosphere.

Electroreduction of CO is an emerging route to produce multicarbon molecules, but achieving this efficiently in solid-state devices is challenging. Here the authors develop a cation-functionalized layer using polyacrylate in a solid-state electrolyser that produces ethylene stably and efficiently from syngas.

The potential roles of viruses in microbial-induced permafrost thaw, which is accelerated by climate change, are unclear. Here, Trubl et al. sample a permafrost thaw gradient and identify thousands of new viruses carrying genes with metabolic-related functions, which might influence the fate of stored carbon.

Applications of optical laser-based techniques are limited by the long wavelengths of the lasers. Now, observations of phonons and thermal transport at nanometre length scales are reported with an all-hard X-ray transient-grating spectroscopy technique.

Evolutionarily related ‘proto-point’ centromeres providing resolution to the evolutionary origins of point centromeres are identified in yeast, and comparison shows they evolved in an ancestor with retrotransposon-rich centromeres and that long-terminal-repeat retrotransposons are the genetic substrate.

The role of normally silenced transposable elements (TEs) in tumorigenesis remains unclear. Here, the authors show that increased expression of TEs in both patients and mice with colitis or by DNA hypomethylating drugs elicits a viral mimicry response that suppresses tumorigenesis. This viral mimicry response inhibits the stemness of cancer initiating cells in a cell autonomous manner.

Groundwater viruses are less well studied. Here, using large-scale sequencing, the authors uncover extensive, largely uncharacterized viral diversity in groundwater, showing that viruses infect dominant microbes, encode genes linked to carbon, nitrogen and sulfur pathways, and thus shape subsurface microbial communities.

Native crystallographic defects are often introduced during synthesis of battery materials, but has been overlooked. Here, using in situ synchrotron X-ray probes and electron microscopy, the authors have revealed their adverse effect during battery operation.

Emerging fungal pathogens have detrimental impacts on crops, animals, and humans, however little is known about their transition to a pathogenic lifestyle. This study demonstrates that the transition from saprotroph to opportunistic human pathogen is likely facilitated by adaptive translation.

A wide survey of pesticide effects on soil biodiversity across 373 sites in Europe reveals that pesticide residues occur in 70% of sites and have major effects on soil biodiversity and functional ecology.

Roles of of viruses in ocean subsurface oxygen maxima are unclear. Here, the authors analyse Bermuda Atlantic Time Series data to show that viruses may drive SOM in stratified oceans by boosting nutrient recycling and phytoplankton productivity linking virus activity to oxygen buildup and a stronger microbial loop.

This Review provides insights into the nanoscale physicochemical and electrochemical processes in non-aqueous electrolyte solutions for lithium metal batteries and explores emerging research directions for accelerated and iterative approaches.

Innovative hydrogen sensors, able to achieve parts-per-billion detection limits with sub-second response times, struggle to enter the market because of inadequate standardization frameworks, as existing frameworks primarily address conventional flammable gases. The disconnection between technical readiness and outdated guidelines prevents the effective deployment of complete hydrogen detection systems. Immediate actions are required to develop a risk-informed, performance-based standardization framework that validates sensor reliability under real-world conditions and provides clear guidance for system integration. Bridging these gaps is essential to prevent infrastructure failures that could undermine substantial investments and public confidence in the global energy transition.

The authors report the synthesis of (La_0.9Y_0.1)H₁₀ superhydrides and their characterization using synchrotron-based, spatially resolved x-ray diffraction and electrical transport imaging. They reveal μm-scale structural inhomogeneity with coexisting cubic and hexagonal clathrate phases exhibiting distinct superconducting transition temperatures.

Fractional Chern insulators have been observed in moiré MoTe₂ at zero magnetic field, but the expected zero longitudinal resistance has not been demonstrated. Now it is shown that improving device quality allows this effect to appear.

Using terahertz spectroscopy and ultrafast electron diffraction, the paper shows how the DC conductivity of warm dense matter depends on material phase. This provides insight to how electron scattering processes impact conductivity in this regime.

This study uses climate model experiments and shows that radiative heating from the presence of clouds can substantially increase the frequency of Euro-Atlantic atmospheric blocking, highlighting the need to better represent cloud-radiation interactions for improved prediction of extreme weather.

Replacing expensive and rare platinum with metal–nitrogen–carbon catalysts in proton exchange membrane fuel cells is limited by their lower activity and stability for oxygen reduction reactions. The authors report Fe-N-C catalyst with trace Br ions to enhance Fe-N4 density and introduce defects and mesopores, achieving high activity for oxygen reduction reaction in proton exchange membrane fuel cell.

This study shows that CrSBr hosts Frenkel-like and Wannier-Mott-like excitons whose distinct spatial character explains their contrasting sensitivity to magnetic order and lattice vibrations, challenging the standard dichotomy in describing excitons.

Electrified CO₂ capture from air could lead to net-negative emissions, yet current methods face high energy costs and sensitivity to oxygen. Here the authors introduce an electrochemical approach using MnO₂ as a stable, redox-active sorbent, achieving CO₂ capture with promising energy consumption and minimal oxygen sensitivity.

The authors report on imaging developments of solid-density plasmas and the current filamentation instability by means of the LCLS-XFEL at SLAC. This offers insights on the instability in the solid density region, stimulating new modelling of laser-solid interactions.

Assessment of 38 seawater-intake facilities along the continental United States coast reveals that large scale deployment of electrochemical marine-based carbon dioxide removal hubs is possible using a multicriteria decision-making framework.

Phaeocystales are ecologically significant nanoplankton whose evolutionary history and functional diversity remain incompletely characterized. Here, the authors integrate genomic and transcriptomic data to reveal their lineage diversification, metabolic plasticity, and adaptation to polar and temperate regimes.

Borgs are large extrachromosomal elements of anaerobic methane-oxidizing archaea. Here, via in silico protein structure prediction of ~10,000 Borg proteins, the authors reveal that Borgs share numerous features with giant eukaryotic viruses, suggesting that Borgs have a viral-like lifestyle and evolutionary convergence of large extrachromosomal elements across the Domains of Life.

The authors demonstrate dual-probe multi-messenger imaging of high-energy-density plasmas based on laser-wakefield-accelerated electrons. This enables spatiotemporally resolved simultaneous probing of plasma hydrodynamics and electromagnetic field evolution with both x-ray and electron beams.

While metal–organic frameworks exhibit record-breaking gas storage capacities, their typically powdered form hinders their industrial applicability. Here, the authors engineer UiO-66 into centimetre-sized monoliths with optimal pore-size distributions, achieving benchmark volumetric working capacities for both CH₄ and CO₂.

Lithium-ion battery cathode lifetime is limited by large expansion and contraction during cycling. This study uses electrochemical activation to suppress collapse in LiNi_0.9Mn_0.1O₂ cathodes, achieving improved capacity and cycle life.

The authors consider the changing sensitivity of the leaf-onset date to temperature (S_T) for boreal deciduous broadleaf forests. S_T increased between 1982–1996 and 1998–2012—potentially linked to enhanced chilling accumulation—but this increase is underestimated in phenology models.

Kinematic measurements of the Perseus galaxy cluster reveal two drivers of gas motions: a small-scale driver in the inner core associated with black-hole feedback and a large-scale driver in the outer core powered by mergers.

Polymer thin films that emit and absorb circularly polarised light are promising in achieving important technological advances, but the origin of the large chiroptical effects in such films has remained elusive. Here the authors demonstrate that in non-aligned polymer thin films, large chiroptical effects are caused by magneto-electric coupling, not structural chirality as previously assumed.

The STAR experiment at the Relativistic Heavy Ion Collider at Brookhaven National Laboratory demonstrates evidence of spin correlations in \(\Lambda \bar{\Lambda }\) hyperon pairs inherited from virtual spin-correlated strange quark–antiquark pairs during QCD confinement.

The advances in artificial intelligence are permeating most scientific domains, and heterogeneous catalysis is no exception. This Perspective discusses the current state and future prospects of AI in heterogeneous catalysis, from the development of an AI-ready data ecosystem to multimodal foundation models and autonomous labs.

Garnet-type LLZO electrolytes are considered among the most promising solid-state electrolytes for all-solid-state batteries; however, numerous challenges need to be addressed before they are integrated into a cell. By precipitating amorphous zirconium oxide onto grain boundaries, increased ionic conductivity is observed and dendrite growth is suppressed.

Terahertz microspectroscopic imaging at subgap millielectronvolt energies of a two-dimensional superfluid plasmon in few-layer Bi₂Sr₂CaCu₂O_8+x is demonstrated, allowing the spatial resolution of its deeply subdiffractive terahertz electrodynamics.

This study shows that using wind speed data with coarser temporal resolution significantly underestimates global wind power density (WPD). A calibration method increases future global onshore WPD estimates by 25% compared to uncorrected daily data.

Identifying jets originating from heavy quarks plays a fundamental role in hadronic collider experiments. In this work, the ATLAS Collaboration describes and tests a transformer-based neural network architecture for jet flavour tagging based on low-level input and physics-inspired constraints.

Ionizing radiation can cause simultaneous charge noise in multi-qubit superconducting devices. Here, the authors measure space- and time-correlated charge jumps in a four-qubit system in a low-radiation underground facility, achieving operation with minimal correlated events over 22 h at qubit separations beyond 3 mm.

Aadvanced computer simulations of three-dimensional turbulence reveal that the ab initio generation of large-scale magnetic fields is driven by shear-flow-induced jets; an analytical model is derived which reproduces the essential features of the flow- and field-generation mechanisms.

Current knowledge of giant virus diversity is largely based on samples from aquatic environments. Here the authors employ cultivation-independent metagenomics and mini-metagenomics on forest soil and identify 16 novel giant virus genomes, some of which representing novel lineages, including the so far largest genome in Mimiviridae.