By utilizing graphene's ability to absorb UV light and distribute heat, researchers have achieved pristine, flexible displays. This advancement opens doors for ultra-thin, stretchable devices that fit comfortably against human skin, revolutionizing wearable device technology.
Researchers used computer simulations to determine the mechanisms that control the temperature dependence of molecular dynamics in a glassy supercooled liquid. This work may lead to higher-quality glass production at lower cost.
New flexible sensor technology transforms ordinary diapers into medical monitoring devices, enabling real-time tracking of morphine and potassium levels through non-invasive urine analysis.
A breakthrough in decoding the growth process of Hexagonal Boron Nitride (hBN) and its nanostructures on metal substrates could pave the way for more efficient electronics, cleaner energy solutions and greener chemical manufacturing.
Researchers used ultrafast laser-induced focal volume light field to achieve one-step fabrication of composite micro-nanostructures in transparent solids with multi-dimensional control.
This novel membrane exhibits remarkable salt permeation and organic matter retention capabilities as well as antifouling properties, making it particularly effective for treating high-salinity organic wastewater.
