A new genetic control system lets lab-grown cells produce gas vesicles step by step, reducing stress on the cells and improving yields for medical uses.

Anomalous low-field oscillatory magnetoresistance in an antiferromagnetic kagome semimetal heterostructure was linked to ...

Carbon nanotubes can open and close in response to acidity, guiding water and ions one by one and mimicking how natural cell ...

Heat limits sub-10 nm chips, but current tools miss nanoscale effects or run too slowly. New modeling bridges atom-level ...

A hybrid graphene and molybdenum trioxide crystal allows real time electrical tuning of Bloch modes and light emission, ...

Researchers adapted ARPES to work in magnetic fields using nanoscale alternating magnets that confine fields near a sample, letting photoelectrons travel straight.

Aircraft wing-shaped structures inside tiny channels produce consistent drug delivery particles at any scale, from small laboratory tests to factory production, while substantially cutting costs.

A semiconductor device generates unforgeable watermarks from chaotic electron behavior, embedding invisible markers in images ...

By changing the physical structure of gold at the nanoscale, researchers can drastically change how the material interacts with light and, as a result, its electronic and optical properties.

A new web-based tool visualizes catalyst gene profiles, helping scientists explore patterns and improve catalyst design.

Ultrathin titanium flow distributors made via laser micromachining achieve record fuel cell power densities, surpassing European aerospace targets set for the end of this decade.

Molecular electronic devices using quantum tunneling could achieve integration densities 1,000 times greater than silicon chips by combining atomic-precision assembly with three-dimensional ...