A five-nanometer-thick layer of silver and copper outperforms conventional indium tin oxide without adding cost.

Researchers developed multiple AI-based approaches for optimizing the ALD processes autonomously. Their work details the relative strengths and weaknesses of each approach, as well as insights that can be used to develop new processes more efficiently and economically.

Using DNA-based assembly, scientists developed a method for creating designed and biologically active 2-D and 3-D protein arrays, which show promise for applications in structural biology, biomaterials, nanomedicine, and biocatalysis.

New metal-free hydrogel electrodes flex to fit the body's many shapes, avoiding damage to organs.

Scientists have used enzymatic crosslinking to create nanofilms on cell surfaces. The 'cell caging' technique can prevent immune rejection during heterologous islet cell transplantation, facilitate smooth cell insulin secretion, and treat type 1 diabetic patients without immunosuppressants.

Researchers use time-resolved photoemission electron microscopy to probe the electron dynamics of solid-state film OLEDs.

Bio-inspired electricity sources could power wearable or implantable electronics in the future, even running on metabolic waste.

Safe and localized delivery of nanoparticle-based anti-inflammatory cytokines programs a specific T cell response that strengthens muscles affected by Duchenne Muscular Dystrophy.

Engineers have assembled what they say may transform chemical catalysis by greatly increasing the number of transition-metal single atoms that can be placed into a carbon carrier.

Researchers showed that using equally sized, or 'monodisperse', perovskite quantum dots results in markedly better performance in Pe-CQD solar cells, paving the way for future optoelectronic devices.