Scientists show how the addition of fullerene-derived carbon materials as catalysts can improve performance, stability, and cost of zinc-air batteries.
Discover a self-growing liquid metal composite that reacts with water for stretchable circuits, soft robotics, and more. This breakthrough enables direct printing of responsive electronics.
Just when it seemed like organic solar cells hit a roadblock, along comes 3PNIN, a game-changing molecule shaped like a propeller, ready to turbocharge their progress and break through barriers.
Scientists have developed a game-changing technique that uses light to manipulate and identify individual bacteriophages without the need for chemical labels or bioreceptors, potentially accelerating and revolutionizing phage-based therapies that can treat antibiotic-resistant bacterial infections.
A comprehensive review outlines how metal organic frameworks-based cathode materials could improve the performance of lithium-sulfur batteries, making them a practical alternative to lithium-ion batteries.
Researchers have published an innovative grayscale nanolithography technique that has potential applications in photonic and nanoelectronic device fabrication.
Researchers have successfully filmed the operations of extremely fast electronic circuitry in an electron microscope at a bandwidth of tens of terahertz.
Researchers have developed a 'self-driving' lab that uses artificial intelligence (AI) and automated systems to provide in-depth analyses of catalytic reactions used in chemical research and manufacturing.
The material delays the formation of ice crystals and reduces the adhesion of ice layers. Thanks to an innovative production method, the coating is very robust and adheres to numerous surfaces.
Researchers have extracted nanocellulose from a waste product of beer brewing and processed it into an aerogel. The high-quality biodegradable material could be used in food packaging.
