Time-tested weaving techniques are utilized to create a remarkably strong, flexible and temperature-resistant fabric with a range of potential applications.

Using fluorescent labels that switch on and off, scientists can study how molecules in a cell interact to control the cell's behavior.

Scientists have revealed how lattice vibrations and spins talk to each other in a hybrid excitation known as an electromagnon. Understanding this fundamental process at the atomic level opens the door to ultrafast control of magnetism with light.

Researchers, using a four-phonon scattering theory, have predicted that graphene's thermal conductivity is lower than previously believed, challenging the notion that it surpasses diamond in this regard.

A promising new therapeutic approach using engineered nanoparticles called carboxyl nanodiamonds has shown dramatic success blocking tumor metastasis in preclinical tests, raising hopes for future clinical impact. Research demonstrates this novel treatment's ability to suppress multiple key steps underlying cancer spread.

Scientists use atomic force microscopy to investigate and manipulate the electrical and magnetic properties of graphene twisted at a specific angle, aiming to understand and reduce energy losses in strongly interacting 2D material systems.

Innovative hybridized technique combines ultrafast laser ablation with controllable in-situ nanoparticle deposition, enabling iterative, layered fabrication of complex multi-tiered hierarchical surface micro- and nanostructures.

Scientists show that porous silica films less than one nanometer thick boost the catalytic activity of a metal palladium surface for carbon monoxide oxidation.

Computing with a combination of light and chargeless excitons could beat heat losses and more, but excitons need new modes of transport.