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Two-dimensional (2D) metal halide perovskites exhibit efficient photoinduced emission at room temperature, but control over charge carrier transport remains limited. Here formamidinium-based layered 2D perovskites are developed with high predicted symmetry. The absence of octahedral distortion results in an exciton diffusion length of 2.5 µm.

Little is known about the transition of a metal nanoparticle from the plasmonic to excitonic state. Here, the authors map this evolution in atomically precise gold nanoparticles, a critical step for understanding the origins of surface plasmon resonance, metallic bonding, and catalytic behaviour.

The addition of squaraine dye to a polymer bulk heterojunction solar cell is shown to enhance light harvesting and cell efficiency through Förster resonance energy transfer.

Intermolecular singlet fission (xSF) has typically been observed when the interchromophore separation is below ∼5.6 Å because the chromophore coupling is dominated by van der Waals forces. Now, using carbon nanohoop assemblies that allow the chromophore assembly and coupling to be modulated, efficient xSF has been observed at chromophore separations distances up to ∼16 Å.

A variant telomerase template demonstrates that human telomeres can tolerate significant degeneracy and remain functional. Once incorporated by telomerase, variant sequences can influence telomere length dynamics.

Polariton-mediated photochemical charge transfer can be identified and quantified in a properly designed photonic system using momentum-resolved ultrafast optical techniques.

Comprehensive analyses of 178 lung squamous cell carcinomas by The Cancer Genome Atlas project show that the tumour type is characterized by complex genomic alterations, with statistically recurrent mutations in 11 genes, including TP53 in nearly all samples; a potential therapeutic target is identified in most of the samples studied.

Using pump-power-dependent exciton absorption spectroscopy, the authors reveal magnon-mediated exciton–exciton interactions and a consequent nonlinear optical response in CrSBr, an antiferromagnetic semiconductor.

In a phase 2 randomized control trial, intermittent senolytic therapy administered to postmenopausal women did not result in a reduction in the bone resorption marker, serum CTx, compared to control at 20 weeks.

Experimental evidence for charge coupling to ferroelectric soft mode is scarce. Here, the authors find a photogenerated coherent phonon coupling to the electronic transition above the bandgap in the van der Waals ferroelectric semiconductor NbOI2.

The Cancer Genome Atlas consortium reports on their genome-wide characterization of somatic alterations in colorectal cancer; in addition to revealing a remarkably consistent pattern of genomic alteration, with 24 genes being significantly mutated, the study identifies new targets for therapeutic intervention and suggests an important role for MYC-directed transcriptional activation and repression.

The Cancer Genome Atlas Network describe their multifaceted analyses of primary breast cancers, shedding light on breast cancer heterogeneity; although only three genes (TP53, PIK3CA and GATA3) are mutated at a frequency greater than 10% across all breast cancers, numerous subtype-associated and novel mutations were identified.

The impact of multiexcitonic through-space interactions in macromolecular architectures is poorly investigated. Here the authors use dendritic macromolecules to study the effect of interchromophore interactions on the dynamics of multiexciton generation and decay as a function of dendrimer generation.

Organometallic perovskite solar cells exhibit good efficiency but their photostability is still relatively poorly understood and controlled. Here the authors show that photo-degradation arises from the formation of light-activated meta-stable trap states, is reversible, and can be frozen at 0 °C.

In organic photovoltaics, the best-performing devices are often based on fullerene derivatives as the electron acceptor counterpart. Here, the authors present new molecular electron acceptors with a helical structure and achieve 8.3% power conversion efficiency.

Principles of quantum interference can guide the design of chromophores that undergo singlet fission. Now, ‘pencil and paper’ graphical models can be used to understand and predict the dynamics of triplet pairs generated through singlet fission in bridged dimers.

Design rules for the synthesis of donor–acceptor systems with efficient intramolecular singlet fission are now proposed. These guidelines have been applied to both small molecules and polymeric chains.

Further mechanistic insight of intramolecular singlet fission (iSF) in conjugated polymers can enable novel material design for solar cells. Here, the authors use transient spectroscopy to show iSF in an isoindigo-based conjugated polymer and propose a design rule based on morphology-dependent iSF.

Experiments show how molecular structure affects the interaction and dynamics of the triplet exciton pairs produced when an excited singlet exciton decays via singlet fission — a process that could be harnessed for optoelectronic applications.

Understanding the process of exciton fission, which occurs in certain organic materials, could lead to the development of more efficient photovoltaic devices. Here, an expression derived from first principles is used to accurately characterize the singlet fission rate of a wide array of materials, reproducing a transition from weak to strong coupling as a function of molecular separation.

Although they are synthetically tunable, organic molecules that undergo singlet fission (the generation of two excitons from one photon) have not demonstrated the excited-state properties necessary to improve optoelectronic devices. Now, a general ‘energy cleft’ molecular design scheme has been demonstrated that enables rapid generation and long lifetimes of multiple triplet excitons that are for device applications.

The Cancer Genome Atlas Research Network reports an integrative analysis of more than 400 samples of clear cell renal cell carcinoma based on genomic, DNA methylation, RNA and proteomic characterisation; frequent mutations were identified in the PI(3)K/AKT pathway, suggesting this pathway might be a potential therapeutic target, among the findings is also a demonstration of metabolic remodelling which correlates with tumour stage and severity.

With a comprehensive analysis of sequencing data, DNA copy number, gene expression and DNA methylation in a large number of human glioblastomas, The Cancer Genome Atlas project initiative provides a broad overview of the genes and pathways that are altered in this cancer type.

Genetic or pharmacological depletion of senescent cells or inhibition of their function reduces bone loss in aged mice.