by | Nov 18, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Graphene Square, a Korean graphene manufacturer, has completed construction of its mass production facility for chemical vapor deposition (CVD) graphene films.A completion ceremony for the plant took place in the southeastern city of Pohang. The plant is expected to...
by | Nov 18, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Electrons can freeze into strange geometric crystals and then melt back into liquid-like motion under the right quantum conditions. Researchers identified how to tune these transitions and even discovered a bizarre “pinball” state where some electrons stay locked in...
by | Nov 16, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
U.S-based biotech company IdentifySensors, developer of graphene-based biosensors, has announced plans to commercialize its disease testing technology and seek new funding in 2026.On its website, the Company states that its Check4™ platform enables rapid, lab-free...
by | Nov 15, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
A few days ago, the International Iberian Nanotechnology Laboratory (INL) and University of Minho (UMinho) signed a licensing agreement with IPLEXMED, a spin-out company specializing in advanced medical diagnostics. The agreement grants the company rights to...
by | Nov 15, 2025 | 2D materials, Aerospace, AGM, Angstron Materials, Audio, Development, Investment, Products, Research
Researchers from IMDEA Nanociencia, Autonomous University of Madrid and INFN recently announced a breakthrough in the engineering of graphene – they found a way to open a bandgap in the material, that allows the flow of electricity in graphene to be controlled...
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.
