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

Cross Section of Gate-All-Around Transistor and Wiring Applied Materials introduced three new chipmaking systems that boost the energy-efficient performance of leading-edge logic chips. The ...

Semiconductor manufacturing is a quickly growing field, which focuses on the design, development and innovation of the processes used to produce the chips that power modern electronics. Almost all of ...

The transition from finFET technology to Gate-All-Around (GAA) technology helps to reduce transistor variability and resume channel length scaling. It also brings several new challenges in terms of ...

Many things about diamonds seem eternal, including the many engineering problems related to making them work as a silicon ...

Nothing is worse for a design team than a chip that fails to work in the bringup lab. Electrical problems are historically a major cause of such failures. Power leaks, power-ground DC paths, missing ...

A bilayer organic transistor with off-on-off current output that can be used to make compact and efficient artificial spiking neurons. The field of wearable/implantable healthcare technology continues ...

As semiconductor manufacturing rapidly expands to meet growing global demand for generative AI and advanced electronics, a ...

Hai “Helen” Li studies neuromorphic computing and AI hardware from a design and computer architecture perspective.

This Collection supports and amplifies research related to SDG 9 - Industry, Innovation and Infrastructure. Electronic devices based on 2D semiconductors are considered one of the most promising ...

New chipmaking systems boost the energy-efficient performance of Gate-All-Around transistors and wiring at 2nm and beyondViva pure radical treatment smoothens GAA silicon nanosheets with atomic-level ...