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.

Researchers at Peking University in China have developed the world’s smallest and most energy-efficient ...

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 ...

Researchers in China say they have created a new silicon-free transistor that could significantly boost performance while reducing energy consumption. The team says this development represents a new ...

What if the thermal noise that hinders the efficiency of both classical and quantum computers could, instead, be used as a ...

Gallium nitride (GaN) is an ideal material for applications requiring high switching speeds and minimal power losses. While ...

In the vast reaches of the semiconductor cosmos, a silent menace lurks—one that can obliterate years of design work in a fraction of a nanosecond. Electrostatic discharge (ESD) verification stands as ...

From quartz sand to silicon wafers, the manufacturing process is critical for achieving the purity and quality needed for ...

Physicist Paul Davies looks back at the past century of quantum mechanics—the most disruptive theory in the history of modern science.