For almost two decades, scientists have been trying to move beyond silicon, the material ...

For nearly two decades, two-dimensional (2D) semiconductors have been studied as a complement or possible successor to silicon transistors, promising smaller, faster and more energy-efficient ...

The research 'Impact of Contact Gating on Scaling of Monolayer 2D Transistors Using a Symmetric Dual-Gate Structure' appeared ...

New research shows 2D carbon materials can store electrical states, reshaping how AI chips manage power and lower electricity ...

New feature provides pixel-level control for dynamic drawing and asset manipulation in Altia Design. By bringing ...

Lab architecture used to test 2D semiconductors artificially boosts performance metrics, making it harder to assess whether these materials can truly replace silicon.

Researchers in the United States have developed a new technique that can spot hidden ...

Duke engineers show how a common device architecture used to test 2D transistors overstates their performance prospects in real-world devices.

Twisting atomically thin magnetic layers does more than reshape their electronics—it can create giant, topological magnetic textures. In chromium triiodide, researchers observed skyrmion-like patterns ...

Future devices will continue to probe the frontier of the very small, and at scales where functionality depends on mere atoms, even the tiniest flaw matters. Researchers at Rice University have shown ...

For nearly two decades, two‑dimensional (2D) semiconductors have been studied as a complement or possible successor to silicon transistors, promising ...

Nanoscale molybdenum disulfide memristors integrated onto standard CMOS chips achieve the lowest switching voltage reported ...