by | Dec 10, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Hememics Biotechnologies, developer of graphene-based biosensing technology, has announced the successful on-site demonstration of its ESAP™ (Electrostatic Sensing for Analyte Profiling) platform at KanPro Research, Inc., a premier protein science and biomanufacturing...
by | Dec 7, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Researchers from Graz University of Technology and the University of Surrey have examined how subtle atomic-level differences between graphene and hexagonal boron nitride (h‑BN) affect the behavior of water on their surfaces. Understanding such water interactions with...
by | Dec 7, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Scientists have discovered how to electrically power insulating nanoparticles using organic molecules that act like tiny antennas. These hybrids generate extremely pure near-infrared light, ideal for medical diagnostics and advanced communications. The approach works...
by | Dec 6, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
SQUIRE aims to detect exotic spin-dependent interactions using quantum sensors deployed in space, where speed and environmental conditions vastly improve sensitivity. Orbiting sensors tap into Earth’s enormous natural polarized spin source and benefit from low-noise...
by | Dec 5, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Kyushu University scientists have achieved a major leap in fuel cell technology by enabling efficient proton transport at just 300°C. Their scandium-doped oxide materials create a wide, soft pathway that lets protons move rapidly without clogging the crystal lattice....
by | Dec 5, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Researchers engineered a strained germanium layer on silicon that allows charge to move faster than in any silicon-compatible material to date. This record mobility could lead to chips that run cooler, faster, and with dramatically lower energy consumption. The...
