Using genetically modified bacteria as an environmentally friendly synthesis platform, researchers produced hybrid solid catalysts for artificial photosynthesis. These catalysts exhibit high activity, stability, and durability, highlighting the potential of the proposed innovative approach.

This is the first study of fatigue behavior on the semiconductor material called 2D hybrid organic-inorganic perovskites (HOIPs) in practical applications.

A new study determines the efficiency of a single-molecule heat engine by considering a series of ratchets that transfer energy along a network.

New research uses protons to shine a light on the structure and imperfections of this two-dimensional wonder material.

By building a structure out of DNA and then coating it with glass, researchers have created a very strong material with very low density.

Scientists have developed a new material concept that potentially allows efficient blue OLEDs with a strongly simplified structure.

Researchers developed an environmentally friendly MXene-based OLED display with high durability with applications in various fields such as automotive display, fashion, medical, safety, etc.

Researchers have created a unique microscopic toolkit of 'green' tuneable electrical components, paving the way for a new generation of bioelectronic devices and sensors.

Researchers are embarking on an ambitious research project to selectively generate defects in atomically-thin semiconductor layers and attempt to measure and control their quantum properties with simultaneous picosecond temporal resolution and atomic precision.

Fast data transmissions could be delivered in homes and offices through light-emitting diodes (LED) bulbs, complementing existing communication technologies and networks.

Researchers explore nanomotors as a biomolecular toolbox to propel precision nanomedicine forward, introducing various propulsion mechanisms to advance diagnostics, drug delivery, and cancer treatments.

A research team has successfully created a quantum bit in a semiconductor nanostructure. Using a special energy transition, the researchers created a superposition state in a quantum dot in which an electron hole simultaneously possessed two different energy levels.