Scientists have twisted DNA into programmable nanostructures that form themselves — and could reshape future materials for light, sound, and electronics.

Scientists have used DNA's self-assembling properties to engineer intricate moiré superlattices at the nanometer ...

CRISPR construct to genetically ablate the GABA transporter GAT3 in the mouse visual cortex, with effects on population-level neuronal activity. This work is important, as it sheds light on how GAT3 ...

Whole-mount 3D imaging at the cellular scale is a powerful tool for exploring complex processes during morphogenesis. In organoids, it allows examining tissue architecture, cell types, and morphology ...

In these instants, a chemical ring might open, an electron might fly away, leaving a positively charged ion behind, or a ...

An attosecond—or 0.000000000000000001 second—is no time at all for a person. That is not so for electrons, atoms and ...

The platform created by the researchers enables the formation and dynamic tuning of photonic crystals with integrated spin-orbit coupling (SOC) and controlled laser emission.

Researchers have observed hydrogen and deuterium molecules in tiny spaces called picocavities using advanced spectroscopy. This study reveals unique differences between the molecules due to ...

A quantum computer has used a single atom to model the complex dynamics of organic molecules interacting with light ...

Polarization of photons plays a key role in quantum optics and light-matter interactions, however, it is difficult to control in nanostructures. Here scientists reveal polarization control of ...

Photonic computing is also particularly suited for performing what are known as matrix multiplications — mathematical operations that are fundamental to AI. Those are some of the benefits.