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The authors report the experimental observation of room-temperature condensation of exciton polaritons in quasi-2D layered crystals of halide perovskite, integrated into an open optical microcavity. These materials combine van-der-Waals properties with dominant exciton physics at room temperature.

An optical-tweezer-based nanorheometer is developed to quantify the viscoelasticity of biomolecular condensates and intracellular compartments in vivo during aging and mutations that cause nuclear envelopathies in a Caenorhabditis elegans model.

Optically active semiconductor quantum dots have so far suffered from nuclear inhomogeneity limiting all dynamical decoupling measurements to a few microseconds. Lattice-matched GaAs–AlGaAs quantum dots now enable decoupling schemes to achieve a 0.11 ms spin coherence time.

Future quantum communication technologies require entanglement between stationary and flying qubits, in systems that are inherently scalable. To this end, De Greveet al.present full state tomography of a qubit pair formed by entangling a quantum dot spin and a photon, with a fidelity of over 90%.

Pulse-excited resonance-fluorescence single-photons are generated on demand from a single quantum dot embedded in a microcavity under s-shell excitation with an ultrafast laser source.

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.

This study elucidates nanoscopic strain evolution in single-crystal Ni-rich positive electrodes, demonstrating that mechanical failure results from lattice distortions, and redefines the roles of cobalt and manganese in battery cycling stability.

Entanglement between single photons and solid-state emitters is a key component for photonic quantum computing and networks. Here, using a single electron spin in a quantum dot, the authors present a deterministic photon source achieving three-qubit entanglement of one electron spin and two photons.

P-selectin recruits leucocytes to regions of blood vessel damage. Using single molecule imaging, we find newly secreted P-selectin spreads rapidly across the plasma membrane and then becomes immobilized and better-suited to leucocyte capture.

Authors combine neutron scattering and MD simulations to study psychrophilic bacteria, linking proteome dynamics to the state of the proteome folding in the context of differential thermal adaptation.

Radical Fe^II/α-ketoglutarate-dependent halogenases are powerful biocatalysts for C–H functionalization. Here, the authors reveal the mechanistic basis for chemoselectivity in a lysine halogenase.

Observations of a fast X-ray transient reveal that it is a gamma-ray-burst explosion from a very distant galaxy that emits light with the wavelength necessary to drive cosmic reionization, the last major phase change in the history of the Universe.

The quark structure of the f₀(980) hadron is still unknown after 50 years of its discovery. Here, the CMS Collaboration reports a measurement of the elliptic flow of the f₀(980) state in proton-lead collisions at a nucleon-nucleon centre-of-mass energy of 8.16 TeV, providing strong evidence that the state is an ordinary meson.

Spectroscopy of a gravitationally lensed galaxy at a redshift of 2.7 with spatially resolved maps of two foreground damped Lyman α systems indicates a vast mass of neutral hydrogen gas, consistent with a star-forming region.

Alloying layers boost the longevity of lithium metal batteries. Here, authors combine nuclear magnetic resonance and impedance spectroscopy to provide insights, revealing enhanced interfacial transport and diminished dead lithium formation as the origins of improved reversibility with Li-Sn alloys.

The authors demonstrate a very stable yet broadly tunable photonic THz source, characterized from 2 GHz to 1.4 THz. A very narrow Lamb dip feature is observed in a water absorption line, showcasing its potential for sub-kHz resolution spectroscopy.

Ca\({}_{3}\)Co\({}_{2}\)O\({}_{6}\) has an unconventional magnetic structure displaying quantum tunnelling phenomena in its magnetization. Here, the authors use s-core-level non-resonant inelastic X-ray scattering to image the atomic Co 3d orbital that is responsible for the Ising magnetism in this system.

Understanding and being able to predict alignment between the electrode Fermi energy and the transport states in the organic semiconductor is important. Here, the authors report an electrostatic model, capable of reproducing the full range of interfacial energy level alignment regimes.

Compared to thin films and other geometries, nanorods can exhibit particularly high performance in solute-intercalation-based energy and information storage devices. Here, the authors use in situ electron microscopy and spectroscopy to study the hydrogenation of palladium nanorods, revealing relationships between nanorod structure and device cyclability and capacity.

Electron spin in quantum dots are extensively studied as a qubit for quantum information processing. However, the coherence of electron spin is deleteriously influenced by nuclear spin. Quantum-dot holes are a potential alternative. Full control over hole-spin qubits is now achieved using picosecond lasers.

Quantum communication requires quantum correlations between the information processing units and the information carrying units. Here, the authors use time-bin encoding and frequency downconversion to telecom wavelengths to achieve kilometre-scale spin-photon correlations.

The authors demonstrate strain-induced morphotropic phase boundary-like nanodomains in lead-free NaNbO₃ thin films, enabling multi-state switching and large enhancements in dielectric susceptibility and tunability over a broad frequency range.

A molecule placed in an optical microcavity behaves as a model two-level quantum system, as demonstrated via laser extinction and interaction with single photons.

The nature and stability of carbon dioxide under extreme conditions relevant to the Earth’s mantle is still under debate, in view of its possible role within the deep carbon cycle. Here, the authors perform high-pressure experiments providing evidence that polymeric crystalline CO₂ is stable under megabaric conditions.

While the impact of F-actin architecture on stress transmission is well studied, the role of architecture on stress generation remains unclear. Here authors use in vitro model and show that distinct organizations constrain myosin motion.

Morphotropic phase boundaries, which separate two competing phases of different chemical composition, are the crucial ingredient for lead-based piezoelectrics. Here, the authors show that similar enhanced properties and analogous thermotropic phase boundaries can occur in simple, lead-free ferroelectrics.

Acetylenes can be covalently linked by oxidative coupling reactions. Zhanget al. report terminal alkyne C_sp-H bond activation and concomitant homo-coupling on a silver surface, yielding polymeric networks with a conjugated backbone.

Properties of relaxor ferroelectrics are governed by polar nanodomains. Polarization rotation facilitated by these domains investigated by means of epitaxial strain reveals a competition between chemistry-driven disorder and strain-driven order.

Despite their importance in plant development and defence the properties of (1,3)-β-glucan remain largely unknown. Here, the authors find that addition of (1,3)-β-glucans increases the flexibility of cellulose and its resilience to high strain, an effect originating in molecular level interactions.

Vibrational fiber photometry enables Raman spectroscopy in the mouse brain with low impact, owing to the use of tapered fibers.

The authors here present geodetic and seismic data for a complete eruptive cycle (2005-2018) for Sierra Negra volcano, Galapagos Island. The data shows the largest pre-eruptive inflation (6.5 m) and rates of seismicity ever observed before a basaltic eruption and provides a rare illustration of caldera resurgence mechanisms.

Although monolayers of N-heterocyclic carbenes (NHCs) readily form on metals, surface reactivity usually hinders their self-assembly on semiconductors. Now, it has been shown that thermally stable, well-ordered monolayers of NHCs can be formed on silicon surfaces. A large reduction in work function is observed and steric effects enable sufficient diffusivity of the NHCs.

Entanglement of the spin of an electron in a semiconductor quantum dot with a single photon is reported, and verified by means of time-resolved frequency downconversion to a telecommunications wavelength; this process is an essential requirement for future quantum networks.

Suture zones are abundant on Antarctic ice shelves and widely observed to impede fracture propagation. Here we show that fracture detainment is principally controlled by the zones’ enhanced seawater contents, reducing fracture-driving stresses by orders of magnitude and therefore greatly enhancing stability.

The ATLAS Collaboration reports a measurement of the ratio of the decay rates of W bosons to τ leptons and muons, in agreement with universal lepton couplings as postulated in the standard model of particle physics.

The Experimental Pilot Line (2D-EPL) project has been launched in 2020 by the European Commission to promote the production of 2D (opto-)electronics and sensing devices. Here, the authors report the results and challenges of the first and third multi-project wafer runs completed at the end of 2022 and 2023 as part of the 2D-EPL.

How to melt and quench the largest subclass of MOFs, metal carboxylate frameworks, into glasses is a major challenge. Here, the authors develop a strategy by grafting the zwitterions onto the carboxylate ligands and incorporating organic acids into the framework channels to realize the glass formation.

Understanding transformations of non-equilibrium materials is a key open scientific question. Here the pathway by which different polar supertextures undergo dynamical correlations and collectively transform into a metastable supercrystal state is revealed experimentally and theoretically over seven orders of magnitude timescale.

In the interfaces of non-magnetic complex oxides, it is unclear which defects are responsible for the magnetic interfaces. Here, the authors find the B-site cation stoichiometry is crucial for the creation and control of magnetism at the interface between non-magnetic ABO₃-perovskite oxides.

Denoising low-counting statistics data in the presence of multiple, unknown noise profiles is a challenging task in scientific applications where high accuracy is required. Oppliger and colleagues train a deep convolutional neural network on pairs of experimental low- and high-noise X-ray diffraction data and demonstrate better performance on experimental noise filtering compared with the case of training on artificial data pairs.

A rational design of deep eutectic solvents (DESs) is hindered because fundamental DES components, such as choline chloride (ChCl), decompose before melting. Here authors determine the melting properties of ChCl, unveiling ionic plastic crystals as a platform for DESs that meet modern sustainability, health, and safety requirements.