by | Sep 21, 2024 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
University of Illinois Chicago scientists have created a new platform to study materials at the level of individual molecules. The approach is a significant breakthrough for creating nanotechnologies that could revolutionize computing, energy and other fields....
by | Sep 20, 2024 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Spintronic devices work with spin textures caused by quantum-physical interactions. Scientists have now studied graphene-cobalt-iridium heterostructures at BESSY II. The results show how two desired quantum-physical effects reinforce each other in these...
by | Sep 20, 2024 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
NanoXplore has reported its financial results for the year ended June 30, 2024. Record total revenues of CAD$38,125,566 (around USD$28,168,000) were reported, compared to CAD$33,318,964 (around USD$24,616,000) last year, representing a 14% increase; Loss of...
by | Sep 19, 2024 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
While silk protein has been used in designer electronics, its use is currently limited in part because silk fibers are a messy tangle of spaghetti-like strands. To address this, researchers from Pacific Northwest National Laboratory, University of Washington, Lawrence...
by | Sep 18, 2024 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Ultra-thin layers of silk deposited on graphene in perfect alignment represent a key advance for the control needed in microelectronics and advanced neural network development.
by | Sep 18, 2024 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Researchers demonstrates the effectiveness of homemade play putty at reading brain, heart, muscle and eye activity. The research outlines the conductive properties of this material, so-named ‘squishy circuits.’
