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The suboptimal optical transmittance of back electrodes and complex fabrication process hindered development of bifacial perovskite solar cells. Here, authors apply single-walled carbon nanotubes as front and back electrodes, achieving power generation density of 36% and bifaciality factor of 98%.

Astrocombs serve as precision calibrators for astrophysical spectrographs by providing a regular sequence of optical lines on a multi-GHz grid. Here, the authors report the first broadband astrocomb in the UV to blue-green spectral region, where stellar absorption lines are most abundant.

Quantum light sources operating at telecom wavelength are a long-sought goal for quantum technologies. Here, the authors show electrically injected emission of single photons and entangled photon pairs from indium phosphide based quantum dots, operating up to a temperature of 93 K.

Atomically thin transition metal dichalcogenides hold promise as scalable single-photon sources. Here, the authors demonstrate all-electrical, single-photon generation in tungsten disulphide and diselenide, achieving charge injection into the layers, containing quantum emitters.

In this work the authors describe antimicrobial peptides (AMPs)-driven phase transitions of intracellular nucleic acids, whereby AMPs induce compaction and phase separation of nucleic acids, resulting in their sequestration and eventual cell death.

Nitrogen-doped lutetium hydride, recently proposed as a superconductor at near-ambient conditions, features distinct color changes from blue to pink to red as a function of pressure. Using theoretical calculations, the authors identify the pink phase as hydrogen-deficient LuH₂ and find that this phase is not a phonon-mediated superconductor near room temperature. Further, the color is controlled by the concentration of hydrogen vacancies.

The detection of high-frequency radiation emitted by a quantum conductor is promising but current approaches exhibit limited sensitivity. Here, Jompol et al. propose on-chip radiation detection based on photo-assisted shot noise and show the response to be independent of the nature and geometry of the quantum conductor.

Frequency comb synthesizers are important for metrology, but they have been difficult to use as frequency rulers in the terahertz region due to their low power. Consolinoet al. phase-lock a quantum cascade laser to a free-space-propagating terahertz comb, demonstrating that they can overcome this limitation.

Nacre is an organic–inorganic composite biomaterial, which consists of an ordered multilayer structure of crystalline calcium carbonate platelets separated by porous organic layers. Finnemoreet al. present a route to artificial nacre which mimics the natural layer-by-layer biosynthesis.

Quantum teleportation enables the transfer of information between different systems, and will be important for building quantum computing networks. Here, the authors show teleportation of photons between two different sources with greatly differing bandwidths, with an average fidelity of 0.77.

Single electron pumps have been proposed as potential candidates for redefining the ampere. This study reports measurements of the quantized current flowing through a semiconductor electron pump with a precision that makes a substantial step towards establishing a direct metric for electrical currents.

Spin–orbit torques could enable a new generation of low-power electrically controlled memory devices. Here, the authors experimentally disentangle the spin-Hall effect and inverse spin-galvanic effect contributions to the relativistic spin torques in a room temperature Fe/(Ga,Mn)As bilayer.

Superconductivity in the iron pnictides is believed to be related to quantum critical fluctuations. Putzke et al. observe unexpected anomalies in the critical fields of BaFe₂(As_1−xP_x)₂that emerge close to its magnetic critical point, which they argue is a generic feature of quantum critical superconductivity.

Experimental studies of hydrogen at high pressure are challenging, so theory is central to understanding its phase behaviour; however, computed phase diagrams do not agree with previous measurements. Here, the authors use a quantum Monte Carlo method and present results in qualitative agreement with experiment.

Thermoelectric devices convert waste heat to electrical power but suffer from low efficiency. Roche et al.create a mesoscopic heat engine comprising capacitively coupled hot and cold electrical circuits in which thermal fluctuations in the former are converted to potential fluctuations in the latter

The melting temperature of hydrogen drops at high pressures, which suggests the possible emergence of a low-temperature liquid state of metallic hydrogen. Chen et al.confirm the existence of this phase in simulations and show how the quantum motion of the protons has a critical role in its stabilization.

Multiferroic materials that exhibit coupled ferromagnetic and ferroelectric characteristics could be useful in the development of non-volatile digital storage. Evans et al. report a single-phase multiferroic material whose room-temperature magnetoelectric coupling appears to be unusually strong.

Control of spin statistics by spin injection from ferromagnetic electrodes has been shown to achieve only weak effects in organic optoelectronic devices. Wang et al.use instead polarization of spins after injection, at high magnetic fields and low temperatures, achieving a 50% change in device characteristics.

In magnetic materials, geometry-defined competing interactions between spins combined with quantum fluctuations can present the possibility of quantum liquid states which do not order even as 0K is approached. Here, the authors present an analogue built from electric dipoles on a triangular lattice.

Manipulation of spins in the solid state is a promising avenue for quantum information and field sensing applications. Bennett et al. demonstrate voltage tunability of single-spin states in a quantum dot as a step towards universal control of a single spin with a single electrical gate.

Future quantum networks will require entangled photons operating in the telecommunications band, so they can integrate with existing architectures. Ward et al.present a quantum-dot-entangled-photon-pair source in this region and a method to measure the fidelity of a time-evolving Bell state.

Many-body localization, which exhibits a fascinating interplay between disorder and interactions, can be studied using ultracold atoms in a quasiperiodic chain. Adding periodic driving makes things even more interesting.

Silicon-vacancy centres in diamond are promising candidates as emitters in photonic quantum networks, but their coherence is degraded by large electron-phonon interactions. Sohn et al. demonstrate the use of strain to tune a silicon vacancy’s electronic structure and suppress phonon-mediated decoherence.

Quantum criticality is often found in metallic compounds that are close to being magnetic. What about insulators in which the electric moments are fluctuating? These too can be described by the same framework—over a wider temperature range than in quantum critical metals.

Singlet exciton fission produces two triplet excited states from one excited singlet through interchromophoric coupling, which is thought to require local order. Now, a triplet yield of 200% and diffusion-limited triplet formation are reported in solutions of TIPS pentacene. Kinetic studies revealed an excimer intermediate and enabled suggestions of design principles for the promotion of singlet fission.

Understanding how excited states behave at heterojunctions between polymers in blends is fundamental to designing better organic solar cells and light-emitting diodes. A quantum-mechanical molecular-scale model of how excitations behave at heterojunctions has been developed, showing an unexpectedly wide but specific range of excitonic states.

Triplet excitons generated in a pentacene layer by singlet exciton fission are transferred to lead selenide colloidal nanocrystals with high efficiency when their energy matches the bandgap of the nanocrystals.

A vibrational wavepacket generated in a spin singlet is shown to be transferable to spin triplets during singlet fission in organic semiconductors, providing a link between multi-molecular singlet fission and single-molecular internal conversion.

Photosynthesis is remarkably efficient. The transport of optically generated excitons from absorbing pigments, through protein complexes, to reaction centres is nearly perfect. Simulations now uncover the microscopic mechanism that drives this coherent behaviour: interactions between the excitons and the vibrational modes of the pigment-protein complex.

Biomolecular condensates with internal structure allow cells to further organise their processes. In this work the authors investigate how condensates can obtain an internal structure with droplets of dilute phase inside via kinetic, rather than purely thermodynamic driving forces.

A central concept for characterising phase-separating systems is the phase diagram but generation of such diagrams for biomolecular systems is typically slow and low-throughput. Here the authors describe PhaseScan, a combinatorial droplet microfluidic platform for high-resolution acquisition of multidimensional biomolecular phase diagrams.

Extrusion bioprinting can be used to produce living materials but controlling cell microenvironments is challenging. Here, the authors use a type of core-shell microgel ink that decouples cell culture from material processing to produce functional materials with a range of potential applications.