Researchers have developed a revolutionary method for creating soft electronic fibers using liquid-metal-embedded elastomers. These fibers achieve unprecedented 925% stretchability while maintaining high conductivity, opening new possibilities for wearable technology. The breakthrough could transfor
Scientists have developed a revolutionary framework called DOMINO-SEE that reveals how climate extremes synchronize across continents. This breakthrough shows droughts and floods occurring simultaneously in distant breadbasket regions, creating unprecedented risks to global food supplies.
Groundbreaking research reveals how interlayer charge redistribution governs both sliding energy barriers and ferroelectric polarization in 2D materials. The findings could lead to more efficient memory devices and sensors with reduced fatigue issues compared to conventional ferroelectrics.
Researchers have made significant progress in understanding the fundamental mechanisms behind sliding ferroelectricity in van der Waals (vdW) materials, according to a recent study published in npj Computational Materials. The research team investigated how interlayer charge redistribution during sliding governs both the energy barrier and ferroelectric properties in these advanced materials, potentially paving the way for more efficient electronic devices.
In a groundbreaking development for cardiovascular medicine, researchers have demonstrated that platelet-derived growth factor-AB (PDGF-AB) significantly improves cardiac function for…
Decoding Chemoresistance Through Epigenetic Landscapes Groundbreaking research published in Scientific Reports has revealed comprehensive DNA methylation signatures that distinguish chemoresistant…
Revolutionizing Battery Technology with Data-Driven Insights In a groundbreaking study published in Nature Communications, researchers have developed a novel approach…
Scientists have developed a novel composite barrier that effectively confines iodide migration in perovskite solar cells. The breakthrough approach combines scattering blocking and dipole monolayer technologies to create durable, high-efficiency solar devices.
Researchers have developed a quantified barrier system that effectively confines iodide migration in perovskite solar cells, according to a recent study published in Nature Communications. The breakthrough addresses one of the most significant challenges in perovskite photovoltaics – the instability caused by iodide ion movement from the perovskite layer to adjacent transport layers. Sources indicate this migration has been a primary factor limiting the commercial viability of perovskite solar cells despite their high efficiency potential.
Revolutionizing Cold Climate Energy Storage In a significant advancement for renewable energy infrastructure, researchers have demonstrated the practical viability of…
A new approach enabling controlled activation of DNA loop extrusion at specific genomic locations is helping scientists understand how genome architecture shapes gene expression. The technique allows researchers to study cohesin’s role in organizing chromatin without disrupting overall genome integrity. This represents a significant advancement over previous methods that relied on global depletion of architectural proteins.
Scientists have developed a novel system that enables controlled activation of DNA loop formation at specific genomic locations, according to reports in Nature Genetics. This breakthrough approach allows researchers to study how the three-dimensional organization of the genome influences gene regulation without disrupting overall cellular function, sources indicate.
Toronto’s Living Laboratory: Tracking Green Roof Health From Above In an unprecedented urban ecology study, researchers from the University of…
