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 ...

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

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

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 ...

Throughout the 20th century, each decade had its own unique set of inventions that left their mark on history. Curious about ...

Aaron Franklin studies nanomaterials as disruptive complements or replacements for conventional silicon technology.

Researchers at UNSW have discovered a new way to make graphene, a remarkable "wonder material," using just discarded peanut ...

It's called NanoFab Reflection. It's expected to cost $614 million to build and is part of a $10 billion computer chip ...

Panelists repeatedly highlighted that AI compute scaling is dramatically outpacing traditional Moore’s Law transistor ...

Quantum computing in 2026 still isn't a faster laptop. It doesn't make email snappier, and it won't speed up spreadsheets.