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

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 ...

In this video, we explore the fundamental components of computers, beginning with transistors and their role in CPUs. The ...

By applying voltage to electrically control a new "transistor" membrane, researchers at Lawrence Livermore National ...

A stunning new imaging breakthrough lets scientists see — and fix — the atomic flaws hiding inside tomorrow’s computer chips. Researchers at Cornell University have achieved something chipmakers have ...

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

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

Adding big blocks of SRAM to collections of AI tensor engines, or better still, a waferscale collection of such engines, turbocharges AI inference, as has ...