A concept for seeded all-or-nothing assembly of micron-scale DNA nanostructures that could extend nanofabrication capabilities and enable creation of highly specific diagnostics.
Researchers have developed the thinnest and most sensitive flow sensor, which could have significant implications for medical research and applications.
Using a technique called optical forging, researchers were able to create structures that are up to 10 000 times stiffer than unmodified graphene. This is record breaking for a material as thin as this.
Stable solid-state emitting, atomically precise nanoclusters with high photoluminescence quantum yield are promising materials for developing large-area printable electronics, mainly for security prints, wearable LEDs, and healthcare sensors.
Scientists have developed a material, nanoporous cubic silicon carbide, that exhibits promising properties to capture solar energy and split water for hydrogen gas production.
Researchers report a novel and simple strategy for the synthesis of dual-component Janus nanoreactor with asymmetric structure to realize bifunction of photocatalytic water oxidation/reduction.
Researchers prepared a nanofiltration membrane with a loose and dually charged separation layer based on a simple catechol-amine chemistry surface engineering strategy.
Researchers have developed a novel asymmetric bilayer carbon nanotubes elastomer/hydrogel composite with integrated actuating and sensing performances.
Researchers demonstrate tunable microparticles that can assemble into larger structures based on the content of attached chemical groups, which may lead to the development of smart sensors or self-healing materials.
Researchers have produced a structural battery that performs ten times better than all previous versions. It contains carbon fibre that serves simultaneously as an electrode, conductor, and load-bearing material.
