Thank you for visiting nature.com. You are using a browser version with limited support for CSS. To obtain
the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in
Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles
and JavaScript.
The path from ordered assemblies of quantum dots to epitaxially connected quantum dot solids is revealed with X-ray scattering and electron microscopy investigations.
Scientists recently gathered in Asilomar, California, to discuss the latest developments in bioelectronics research. Interfaces between our body and advanced technologies for biomedical and other applications are becoming ever more diverse and effective.
Reducing the thickness of an amorphous conductive indium tin oxide layer down to a few nanometres has enabled the realization of 40-nm-long channel transistors with remarkable operating characteristics.
Hematopoietic stem and progenitor cells have been engineered using gold nanoformulations conjugated with CRISPR capable of targeting two distinct genomic loci of therapeutic interest, with potential engraftment in humanized mouse models.
A high-spatial-resolution force microscopy method combined with a model of cellular mechanics quantifies intracellular forces from nanoscale stiffness patterns at the cell membrane.
Understanding the mechanics of acute kidney injury from toxins, ischemia and sepsis remains challenging. Molecular probes with high renal clearance have now been developed for real-time optical detection of early-stage biomarkers of drug-induced acute kidney injury, and for the understanding of the mechanisms of injury.
Lewis acids are shown to react with water, forming a complex with Brønsted acidity able to effectively dope semiconducting polymers through backbone protonation and internal charge transfer.
Progress in utilizing spin current as a probe of quantum materials,—including topological insulators, superconductors, spin liquids, magnonic systems and spin superfluidity,—is reviewed.
Materials that permit spatiotemporal control of biomolecule presentation have long been a challenge in the field. A method has now been developed to reversibly pattern cell-laden hydrogels with site-specifically immobilized proteins using sortase-mediated transpeptidation without compromising bioactivity.
Solid-state batteries are attractive due to their potential safety, energy-density and cycle-life benefits. Recent progress in understanding inorganic solid electrolytes considering multiscale ion transport, electrochemical and mechanical properties, and processing are discussed.
From optoelectronic to biomedical and energy storage applications, the interest in organic mixed ionic–electronic conductors is expanding. This Review describes current understanding of the processes occurring in these materials and their structure–property relations.
With their ability to give rise to many different cell types, stem cells have long been a target of scientists who seek to achieve control over their differentiation. New evidence suggests that stem cells influence their own fates through protein deposition and physical remodelling of their microenvironment.
Violating the Aufbau principle is shown to be a successful strategy to improve the stability of neutral organic radicals used in organic light-emitting diodes.
Thousands of electron diffraction patterns, collected stepwise by scanning transmission electron microscopy, are synchronized and mined to provide unprecedented maps of the nanostructure of ordered domains in organic electronics films.
