by | Nov 14, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Laser light can physically distort Janus TMD materials, revealing how their asymmetrical structure amplifies light-driven forces. These effects could power breakthroughs in photonic chips, sensors, and tunable light technologies.
by | Nov 13, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
NanoXplore has announced it has entered into an exclusive, long-term supply agreement with Club Car, a leading name in the recreational products industry.This partnership will support the production of graphene-enhanced, high-performance solutions. The addition of...
by | Nov 13, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Scientists have developed a new way to build rare-earth crystals that boosts quantum coherence to tens of milliseconds. This leap could extend quantum communication distances from city blocks to entire continents. The method uses atom-by-atom construction for...
by | Nov 12, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Boron arsenide has dethroned diamond as the best heat conductor, thanks to refined crystal purity and improved synthesis methods. This discovery could transform next-generation electronics by combining record-breaking thermal conductivity with strong semiconductor...
by | Nov 12, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Developing autonomous sensor systems capable of sustained operation without battery dependence is essential for the Internet of Things. A recent study by researchers from the University of Arkansas and the University of Michigan demonstrates how graphene–silicon solar...
by | Nov 11, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
UC Santa Barbara physicists have engineered entangled spin systems in diamond that surpass classical sensing limits through quantum squeezing. Their breakthrough enables next-generation quantum sensors that are powerful, compact, and ready for real-world use.
