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Mixed-stack complexes consisting of alternating donors and acceptors typically show low electrical conductivity. Here, the authors improved the conductivity by hybridizing the frontier orbitals of the donor and acceptor at the neutral–ionic boundary.

The realization of a BT.2020 blue emitter is challenging due to the spectral redshift associated with π-extension. Here, the authors report a multi-resonance thermally activated delayed fluorescence emitter, exhibiting ultrapure deep-blue narrow emission and CIEy ≤ 0.05 exceeding 20% efficiency.

All-polymer solar cells comprising both polymeric donors and acceptors offer better morphological and mechanical stability, and a broader processing window for printing. Here, the authors report a polymer acceptor based on bithiazole linker with more coplanar and ordered molecular conformation.

The insertion of metal atoms and heteroaromatic units provides a way to tune the optical, electronic and magnetic properties of graphene nanoribbons. Now the synthesis of a porphyrin-fused graphene nanoribbon with a narrow bandgap and high charge mobility has been achieved, and this material used to fabricate field-effect and single-electron transistors.

Discovery of 2D materials with useful electronic properties is challenging. Here, the authors use DFT to design a stable semiconducting 2D carbon allotrope for optoelectronic applications that has light charge carriers and unusual secondary bandgap.

Though charge transport in molecular devices depend on the electrode-molecule interface, controlling the interface’s contact geometry remains a challenge. Here, the authors report molecular junctions featuring TTF-fused NDI molecules anchored to gold electrodes through direct TTF-Au contacts.

The mechanism underpinning the photovoltaic effect in hybrid perovskite solar cells has remained unclear. Here, Green and co-workers suggest that iodide ions in methylammonium lead iodide perovskite migrate via interstitial sites and undergo a redox reaction to form molecular iodine and free electrons.

Batch-to-batch reproducibility of device performances is crucial for perovskite photovoltaics moving towards industrialization. Here, the authors show that commercial as-received C₆₀ source materials may coalesce during repeated thermal evaporation processes, jeopardizing such reproducibility.

Fabricating materials with simultaneously spontaneous magnetic and electrical polarisations is challenging due to contradictory electronic features. Here, the authors report a synthesis path toward a perovskite MnSrTa₂O₇ by performing low-temperature cation-exchange reactions on Li₂SrTa₂O₇.

In this work, authors show that O-redox in 4d and 5d transition metal oxides involves the formation of molecular oxygen trapped in the particles. These results are in accord with observations in 3d oxides and show that the greater covalency of the 4d and 5d oxides does not stabilise peroxo-like species.

Fabrication methods for ionic conductive hydrogel fibers are challenged by complexity and poor stability. Using a stress-induced adaptive phase transition strategy, Liu et al. fabricate self-encapsulated hydrogel fibers for depth-of-field sensing applications in a sustainable, two-step process.

Few-layer molybdenum ditelluride and tungsten diselenide field-effect transistors can be reversibly doped with different carrier types and concentrations using pulses of ultraviolet and visible light, allowing reconfigurable complementary metal–oxide–semiconductor circuits to be created.

Fluorinated polyacetylene has typically proven to be inaccessible using traditional polymer synthesis, but there is much interest in its predicted properties. Now, a mechanochemical unzipping strategy has succeeded in the synthesis of a gold-coloured, semiconducting fluorinated polyacetylene with improved stability in air compared to polyacetylene.

Constructing artificial ion channels to mimic biological process is highly demanded but currently artificial ion channels lack robustness. Here the authors report a robust NO-regulated artificial nanochannel based on a spiro ring opening−closing reaction strategy.

Charge ordering in magnetite is an important example of the complex behaviour that emerges in transition metal oxides. Here the authors show that doping causes selective oxidation of one site in the established trimeron pattern, introducing an additional charge-ordered structure.

Solid-state rechargeable batteries using solid electrolytes instead of liquid ones could address the safety and energy density issues. Here the authors report a Na-ion solid electrolyte Na_2.88Sb_0.88W_0.12S₄ which exhibits record high ionic conductivity of 32 mS/cm at room temperature.

Electrochromic displays that are stable in the coloured state for up to 52 h with no applied voltage are fabricated using molecules hosting concerted intramolecular proton-coupled electron transfer processes.

Nanoscale optoelectrodes hold the potential to optically stimulate individual neuron. Here, the authors form nanoscale capacitive optoelectrodes by incorporating zinc porphyrin into nanorods, coated by TiO2, a design that allows for far-field optical modulation of neurons with efficiency and negligible side effects.

We synthesized a new benzobisthiazole (BBTz) containing building unit in which two alkoxythiophenes were attached to the BBTz moiety so as to induce oxygen–sulfur noncovalent intramolecular interactions and thereby interlock the linkage. As a result, the π-conjugated polymer incorporating the new building unit, PDBTz2, had a more coplanar and rigid backbone than the alkyl counterpart, PDBTz1. Interestingly, the backbone orientation was completely altered from the edge-on orientation (PDBTz1) to the face-on orientation (PDBTz2), which is preferable for organic photovoltaics. Accordingly, PDBTz2 showed a much higher photovoltaic performance than PDBTz1.

The electronic properties of bulk solids composed of zwitterionic tetrathiafulvalene-extended dicarboxylate radicals are investigated, showing highly conducting metallic behaviour in single-component molecular systems having only s and p electrons.

Effective band-gap engineering of armchair graphene nanoribbons calls for control over both width and edge structure. Here, the authors report a modular synthesis of narrow N = 6 armchair graphene nanoribbons whose edges can be unsymmetrically modified with heteroarenes, introducing a simple way to tune band gap.

Hygroelectric generators comprised of electrodes and a hygroscopic material with a chemical-gradient structure can produce electricity by absorbing water vapor. Here, the authors achieve a high output voltage by employing hygroscopic heterogeneous graphene oxide and materials with Schottky junctions.

Electronic phase separation is an important feature of many correlated perovskite compounds but hasn’t been seen in other complex oxides with similar physical behaviour such as magnetite. Hong et al. find phase separation between a magnetite-like charge ordered phase and a charge averaged phase in CaFe₃O₅.

Perylene diimide-bithiophene macrocycles are electroactive and shape-persistent hosts. Here, the authors describe their self-assembly into a cellular organic semiconducting film whose voids are electrically sensitive to different guests, and which can function as the active layer in a field-effect transistor device.

Inorganic α-Ag₂S semiconductor, which has preferential slip planes in the crystal structure and irregularly distributed bonds of silver atoms preventing cleavage, demonstrates metal-like ductility at room temperature.

One of the goals for devices using organic semiconductors is to make the materials themselves multifunctional or tunable, reducing the complexity of the device. Now, a film created by blending two components is shown to be phototunable with bistable energy levels and has been used in an organic thin-film transistor.

The controlled functionalization of single-walled carbon nanotubes has been shown to brighten their photoluminescence up to 28 times, which challenges our current understanding of how chemical defects affect low-dimensional carbon materials. This significantly improved photon conversion efficiency promises to advance a broad range of optoelectronic and imaging applications based on carbon nanotubes.

Understanding the intrinsic electronic properties of building blocks in conjugated materials can provide powerful design guidelines to control charge transport, such as tuning the nature of the charge carriers. Now, single-molecule transport studies of a family of oxidized oligothiophenes have shown that their molecular length determines the dominant carrier type.

The ability to self-heal is an important survival feature in nature, with in-built systems working to correct faults and extend the lifetimes of organisms. Now, self-healing chemistry has been applied to overcome the short cycling lifetime of high-capacity rechargeable lithium-ion batteries with silicon-microparticle anodes that suffer from mechanical fractures.

A flexible n-type material has been developed with a thermoelectric figure of merit of 0.28 at 373 K via the intercalation of organic cations between titanium disulphide monolayers.

Transparent conductive electrodes are widely used in modern optoelectronic devices, but they are rarely transparent in the near-infrared, limiting their use. Nanostructured bismuth selenide, a topological insulator, is now shown to be a flexible near-infrared transparent electrode.

Chemical approaches to improve aqueous dispersions of conjugated polymers are limited by the feasibility of modifying the backbone or lead to poor performance. Here, Liu et al. show that ground-state electron transfer in donor:acceptor blends aids aqueous dispersion, for high conductivity and solubility.

Rhenium chalcohalide cluster compounds are promising photoluminescent materials. Here the authors report a new material in this family, Rb₆Re₆S₈I₈, which shows broad photoluminescence (PL) range, high PL quantum yield and long PL lifetime.

Few studies have investigated the structural properties of organic mixed ionic-electronic conductors in relation to the transient device characteristics. Here, Kim et al. show that backbone-dependent molecular orientation affects ion injection directionality, which determines ion mobility and transient response.

The water surface has recently proven to be an effective platform for the synthesis of large-area two-dimensional polymers with high crystallinity. Here, the authors report the on-water synthesis of a crystalline monolayer 2D polyimide, as well as its incorporation into organic–inorganic hybrid van der Waals heterostructures that display significant charge transfer and high electron mobility.

3D microprinting is considered a next generation manufacturing process for microscale components. Here, authors develop a generalised microscale 3D printing method to produce purely inorganic nanocrystal-linked porous materials that exhibit excellent functionality and hierarchical porosity.

Though triplet-triplet upconversion is a promising strategy for designing new deep blue-emitting organic materials, maximizing the efficiency of this process remains difficult. Here, the authors report the upconversion efficiency in anthracene derivatives based on a spin-orbit coupling mechanism.

Designing high performance organic neuromorphic devices remains a challenge. Here, Liu et al. report the development of an organic synapse based on a semicrystalline polymer PBFCL₁₀ with device dimension of 50 nm and integration size of 1 Kb and a mixed‐signal neuromorphic hardware system based on the organic neuromatrix and FPGA controller for decision‐making tasks.

The film uniformity is essential to the fixed pattern noise (FPN) and resolution of X-ray detectors. Here the authors demonstrate the rheological engineering of the perovskite suspension to achieve low FPN of 1.39% and high resolution of 0.51 lp/pix.

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.

Solid polymer electrolytes are crucial for the development of lithium batteries, but their lower ionic conductivity compared with liquid/ceramics at room temperature limits their practical use. Precise positioning of designed repeating units in alternating polymer sequences now allows the Li⁺ conductivity to be tuned by up to three orders of magnitude.

Reducing non-radiative energy loss is critical to improving power conversion efficiency in organic solar cells. Jiang et al. show that alkyl side-chain engineering in acceptors reduces the free volume ratio, lowering non-radiative decay, to achieve 18.6% efficiency in bulk-heterojunction binary cells.

Here the authors report Zn porphene, a member of a new organic metalloporphene family. Similar to graphene, these also are fully conjugated 2D polymers, but are composed of fused metalloporphyrin rings.

Cation intercalation is an effective method to optimise the electronic structures of metal oxides. Here authors present a visual intercalation chemical synthesis strategy to control intercalated structures of metal oxides and synthesise flexible conductive metal oxide films in one minute at room temperature.

GaUDI is a guided diffusion method for the design of molecular structures that features a flexible and scalable target function and that achieves high validity of generated molecules.

Stretchable electronics are attractive for a range of biomedical applications, but are challenging to prepare with suitable mechanical properties. Here, the authors report the use of a soft interlayer that allows the development of stretchable electronics with tissue-like material properties.

The two-dimensional layered crystal structure of niobium oxide polymorph T-Nb₂O₅ exhibits fast Li-ion diffusion that is promising for energy storage applications. Epitaxial growth of single-crystalline T-Nb₂O₅ thin films with ionic transport channels oriented perpendicular to the surface are now demonstrated.

Broadband spectral photoresponse has potential for optoelectronic devices, but obtaining high photoactivity beyond the material bandgap is challenging. Here, the authors report the development of a molecular pyroelectric material with broadband photopyroelectric effects.

Keto-enol tautomerism offers a promising platform for modulating charge transport at the nanoscale. Here, the authors show that the keto-enol equilibrium can be modulated on the single-molecule scale by controlling charge injection in a two-terminal junction system.