Chinese researchers advance gallium oxide tech for military electronics

Chinese scientists have developed a supercooling innovation that boosts the performance of gallium nitride chips used in military radar by 40%. This technology, from Xidian University, enhances radar detection in stealth aircraft without increasing chip size. It also offers wider signal coverage and lower power costs for mobile networks.

25. Februar 2026 Von KI berichtet

Chinese researchers have achieved a breakthrough in ferroelectric transistors (FeFETs), overcoming long-standing limitations of traditional versions and paving the way for large-scale applications. These transistors function similarly to neurons in the human brain, integrating memory and processing in a single unit to reduce data transfer time.

Researchers have created a method to manage electronic friction in devices, potentially leading to more efficient technology. By using specific materials and applying pressure or voltage, they can reduce or eliminate this hidden energy loss. The breakthrough focuses on electron interactions in smooth surfaces.

25. Januar 2026 Von KI berichtet

Researchers at Japan's RIKEN Center for Emergent Matter Science have pioneered a method to carve three-dimensional nanoscale devices from single crystals using focused ion beams. By shaping helical structures from a magnetic crystal, they created switchable diodes that direct electricity preferentially in one direction. This geometric approach could enable more efficient electronics.

Researchers at Florida State University have created a novel crystalline material that exhibits complex swirling magnetic behaviors not found in its parent compounds. By blending two structurally mismatched but chemically similar materials, the team induced atomic spins to form skyrmion-like textures. This breakthrough, detailed in the Journal of the American Chemical Society, could advance data storage and quantum technologies.

15. Januar 2026 Von KI berichtet

Researchers at TU Wien have uncovered a material where electrons no longer act like distinct particles, yet it still exhibits topological properties thought to require such behavior. This discovery in the compound CeRu₄Sn₆ challenges long-held assumptions in quantum physics. The findings suggest topological states are more universal than previously believed.