Of the many feats achieved by artificial intelligence (AI), the ability to process images quickly and accurately has had an ...

Silicon carbide is for photonic circuits and quantum devices. Atomic layer processing boosts SiC waveguides and resonators, improving performance.

Researchers at Incheon National University are addressing this challenge by presenting a comprehensive roadmap for ultra thin crystalline silicon based ...

For decades, chipmakers have squeezed more computing power out of silicon by shrinking transistors, but that strategy is running into hard physical limits. A new approach from MIT aims to sidestep ...

The advent of big data era raising significant challenges in information processing, especially in the aspect of capacity and power consumption. Situations become even worse when we consider the fact ...

In the world of electric (EV) and software-defined vehicles (SDV), a key challenge and opportunity besets original equipment manufacturers (OEM): that of effectively harnessing in-vehicle and silicon ...

Ultra-thin crystalline silicon is an exciting material for next-generation bioelectronics, transforming rigid silicon into flexible nanomembranes while preserving superior electrical performance and ...

SiSiC (reaction bonded silicon carbide, also known as RBSIC) grinding buckets are engineered to handle severe mechanical wear, impact, and chemical exposure. Compared with metal, polymer-lined, or ...

Researchers from KAUST, TU Delft, and LMU Munich have improved the performance of monolithic perovskite-silicon tandem solar cells by modifying the physical structure at the front of the bottom ...

Researchers from the Max Planck Institute for the Science of Light and the Fraunhofer Institute for Integrated Systems and Device Technology IISB are advancing silicon carbide as a key material ...