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Strongly enhanced optical nonlinearities and an ultrafast transition from coherent to incoherent polariton excitations are demonstrated by coupling an atomically thin WS₂ layer to a plasmonic nanostructure using ultrafast multidimensional spectroscopy.

Estimates from the Global Burden of Disease study reveal declines in chronic respiratory disease mortality between 1990 and 2023—especially during the COVID-19 pandemic—but the burdens on people affected remain substantial.

Here, the authors introduce a cryogenic scanning probe photoelectrical sensing technique, termed exciton-resonant microwave impedance microscopy, to measure the excitonic responses in monolayer MoSe2 and identify exciton polarons and their Rydberg states.

Phosphorene nanoribbons demonstrate extraordinary magnetic properties, ranging from large internal fields in films to macroscopic alignment in solution, which can be coupled to photoexcitations that localize to the magnetic edge of these ribbons.

Previously, superradiance was observed from sizeable crystals or close to liquid-helium temperatures. Here, Bradec et al. report the observation of room-temperature superradiance from single, highly luminescent diamond nanocrystals with spatial dimensions much smaller than the wavelength of light.

Vapour-phase methods are promising for nanomaterial synthesis but the vaporization of different precursors for the synthesis of a broad nanomaterial space is challenging. Here electrified vapour deposition generates ultrahigh-temperature, high-flux atomic vapour at atmospheric pressure to rapidly vaporize diverse precursors, enabling the synthesis of multi-elemental nanomaterials with uniform compositions and tunable structures.

The ultrafast optical control of resonances in temporally symmetry-broken metasurfaces allows resonances to be created, annihilated or programmably manipulated, which is useful for applications that require active real-time tunability.

Unlike conventional lasers that require a uniform resonant cavity to operate, random lasers use a highly disordered gain medium in which scattering is dominant. Hokr et al. report Raman lasing from a bulk three-dimensional disordered medium whose intensity exceeds that of other random lasers by many orders of magnitude.

Photoexcitation of quadrupolar dyes—key materials for various optoelectronic applications—induces an excited-state symmetry-breaking charge-transfer process with unknown microscopic origin. Now it has been shown that vibronic coupling to high-frequency backbone modes drives the initial ultrafast symmetry breaking before solvation, distinguishing fundamental intramolecular dynamics from solvent-induced charge localization.

An ultrastrong exciton–polariton coupling in two-dimensional excitonic mithrene with a large refractive index and a large oscillator strength of its primary exciton is reported, enabling the formation of self-hybridized exciton–polaritons with Rabi splitting of >600 meV.

Function-altering variants of immune-related genes cause rare autoimmune syndromes, whereas their contribution to common autoimmune diseases remains uncharacterized. Here the authors show that rare variants of lupus-associated genes are present in the majority of lupus patients and healthy controls, but only the variants found in lupus patients alter gene function.

The activation of dioxygen at metal centres, and subsequent functionalization of unactivated C‒H bonds, requires the generation of high-energy radical intermediates that often result in undesirable side reactions. Now an elusive oxygen-derived reactive iron(II)–radical intermediate is spectroscopically characterized as part of a strategy to stabilize phenoxyl radical cofactors during substrate oxidation reactions.

Characterizing surfaces by Raman spectroscopy is limited by the competition of surface and bulk Raman responses. Here the authors use nanoporous plasmonic membranes to enhance surface Raman signals while suppressing bulk contributions.

Functionalized InAs quantum dots emitting in the short-wavelength infrared spectral region enable functional biomedical imaging at unprecedentedly high spatial resolution, deep penetration and fast acquisition speeds.

Virgilio et al show that HIV Vpr promotes the degradation of the myeloid transcription factor, PU.1, to prevent the expression of PU.1-regulated antiviral factors that would otherwise target HIV Env and inhibit viral spread in macrophages.

Lymphotoxin beta receptor (LTβR) signalling regulates leukocyte migration through the lymphatic endothelial layers. Here, the authors show that treatment of an LTβR-derived decoy peptide can target the non-classical NFκB pathway to inhibit T cell and dendritic cell migration and ameliorate contact hypersensitivity in mouse models.

Two-dimensional hybrid perovskites have gained substantial interest recently due to their controllable optoelectronic properties; however precise control over layer thickness has been synthetically challenging. Now a crystal growth method is shown to achieve high-quality single crystals of organic semiconductor-incorporated perovskites with control over their thickness and length through judicious solvent choice, affording precisely tuned optoelectronic properties.

Long operational stability is essential to commercialisation of organic solar cells. Here, the authors investigate the thermal degradation of inverted photovoltaic devices based on PM6:Y6 non-fullerene system to reveal that trap-induced transport resistance is primarily responsible for the drop in fill factor.

Mixed-halide perovskites are of interest for photovoltaic devices, but light-induced halide segregation obstructs bandgap tuning and is not fully understood. Here the authors study the effects of strain and iodide/bromide ratio on light-induced halide segregation in mixed-halide perovskites.

The authors uncover a coherent, long-range transport of excitons in organic semiconductors that are strongly coupled to spatially structured plasmon fields by tracing ultrafast Rabi oscillations using two-dimensional electronic spectroscopy.

Membranes made of metal-coated silicon nitride can be used to assemble van der Waals heterostructures without a polymer support layer, thus improving cleanliness and allowing assembly at more extreme temperature and vacuum conditions.

Enhancement techniques are a viable route to improve the intrinsically weak Raman scattering intensity. Here the authors demonstrate Purcell enhancement of Raman scattering in a tunable, high-finesse microcavity and use it for Raman imaging of individual carbon nanotubes

Surface chemistry controls the location of WSe₂ nucleation on a stepped sapphire substrate. Preferential nucleation at either the top or bottom step edge can be used to minimize mirror twin domains and produce unidirectional WSe₂ monolayers.

A two-dimensional crystalline polymer of C₆₀, termed graphullerene, is synthesized by chemical vapour transport, and mechanically exfoliated to produce molecularly thin flakes with clean interfaces for potential optoelectronic applications.

Molecular chaperones are recognized to interfere with protein aggregation, yet the underlying mechanisms are largely unknown. Here, the authors develop a kinetic model that reveals the variety of distinct microscopic mechanisms through which molecular chaperones act to suppress amyloid formation.

The authors present nanosensor chemical cytometry, based on an array of nIR fluorescent single walled carbon nanotube integrated along a microfluidic channel. The lensing effect of the flowing cells allows for extracting information, and correlating biomolecular information with physical properties.

CLPP-deficiency-driven mitochondrial dysfunction in brown adipose tissue leads to the accumulation of d-2-hydroxyglutarate, in turn promoting lipid-droplet enlargement by altering gene expression and epigenetically regulating nuclear stiffness.

Imparting non-native functions to living plants using nanoparticles opens the possibility of creating synthetic materials that can grow and repair themselves using sunlight, water and carbon dioxide. It is now shown that, both in plant extracts and living leaves, carbon nanotubes traverse and localize within the lipid envelope of plant chloroplasts, enhance their photosynthetic activity, and enable near-infrared fluorescence monitoring of nitric oxide.

Designing conjugated polymers with high charge carrier mobility and fluorescence quantum efficiency, though attractive for optoelectronics, remains challenging. Here, the authors report a strategy for designing donor-acceptor copolymers whose optoelectronic properties exceed the state-of-the-art.

Plants can be engineered to serve as self-powered pre-concentrators and autosamplers of analytes in ambient groundwater and as infrared communication platforms that can send information to a smartphone.

Dimethyl fumarate (DMF) is an anti-inflammatory drug proposed as a treatment for COVID19. Here the results are reported from a randomised trial testing DMF treatment in 713 patients hospitalised with COVID-19. DMF was not associated with any improvement in day 5 outcomes.

Contradictory models are being debated on the dominant pathways of charge generation in organic solar cells. Here Kurpiers et al. determine the activation energy for this fundamental process and reveal that the main channel is via thermalized charge transfer states instead of hot exciton dissociation.

The epigenome has been shown to change with age, potentially impacting on ageing-related disease. Here the authors investigate the DNA methylation state of the genomic loci of human tRNA and observe enrichment for age-related DNA hypermethylation at tRNA loci.

A study using a mouse solid tumour model suggests that adjusting the dosing frequency of the PI3Kδ inhibitor AMG319 in the treatment of human cancers could decrease tumour growth with fewer adverse effects.

This study presents an extensive molecular characterization of the reprograming process by analysis of transcriptomic, epigenomic and proteomic data sets describing the routes to pluripotency; it finds distinct routes towards two stable pluripotent states characterized by distinct epigenetic events.

When high-harmonic emission from a ZnO crystal is perturbed with a bright squeezed vacuum beam, a comb of super-bunched high-order sidebands is created. This indicates photon bunching and the generation of a non-coherent state at the short wavelength.

Early stellarator designs suffered from high particle losses, an issue that can be addressed by optimization of the coils. Here the authors measure the magnetic field lines in the Wendelstein 7-X stellarator, confirming that the complicated design of the superconducting coils has been realized successfully.

Data collected from more than 2,000 taxa provide an unparalleled opportunity to quantify how extreme wildfires affect biodiversity, revealing that the largest effects on plants and animals were in areas with frequent or recent past fires and within extensively burnt areas.

Tailored ultrafast resonances (in amplitude, Q-factor, wavelength) in an unpatterned thin Si film driven by permittivity asymmetries. Spectrally selective third-harmonic generation (THG) enhancement is shown accordingly.

Synthesis of MoS₂ on a silicon surface pre-treated with phosphine enables the growth of one-dimensional MoS₂ nanocrystals with tunable dimensions and optical properties.