by | Jan 25, 2026 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Graphene Connect 2026 is fast becoming the must‑attend virtual gathering for the global graphene and 2D materials ecosystem, and there has never been a better time to secure your place. Over two days on 11–12 March 2026, industry leaders, researchers, and innovators...
by | Jan 25, 2026 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Rice University researchers from the lab of James Tour have shown that Thomas Edison’s original 1879 carbon-filament light bulbs possibly included a graphene-forming regime, suggesting that one of history’s most iconic inventions may have inadvertently produced...
by | Jan 24, 2026 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Researchers at Canada’s McGill University recently reported two separate studies focused on the development of ultra-thin materials based on graphene oxide films, that can move, fold, and reshape themselves, opening new possibilities for soft robotics and...
by | Jan 22, 2026 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Monash Health and Monash University have received a $100,000 research grant from the Love Your Sister Foundation, through the Monash Health Foundation, to develop a graphene oxide (GO)-based biosensor for early cancer detection using circulating tumor DNA (ctDNA). The...
by | Jan 22, 2026 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
A long-standing law of thermodynamics turns out to have a loophole at the smallest scales. Researchers have shown that quantum engines made of correlated particles can exceed the traditional efficiency limit set by Carnot nearly 200 years ago. By tapping into quantum...
by | Jan 22, 2026 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Scientists are learning how to temporarily reshape materials by nudging their internal quantum rhythms instead of blasting them with extreme lasers. By harnessing excitons, short-lived energy pairs that naturally form inside semiconductors, researchers can alter how...
