A transdisciplinary Northwestern University research team has developed a revolutionary transistor that is expected be ideal for lightweight, flexible, high-performance bioelectronics. The ...

Cornell researchers have developed a new transistor architecture that could reshape how high-power wireless electronics are ...

A new type of transistor could bring about a bevy of innovative electronic applications, ranging from wearables to implants to IoT devices, due to the tiny amount of power it uses. Developed by ...

What many engineers once saw as a flaw in organic electronics could actually make these devices more stable and reliable, ...

The team’s wooden transistor has a few advantages that might help it find eventual applications. Being biodegradable could help reduce the e-waste problem, and the large conductive channels could let ...

Traditional CMOS chips are fabricated by applying and then etching repeated layers of different materials, applied to a wafer ...

On a physical level, a transistor’s internal functioning is very complex, but, in practice, using it in some simple experiments is quite easy and affordable for everyone. A transistor allows to create ...

How can the performance of flexible electronics be improved through the unlikeliest changes? This is what a recent study ...

For decades, chipmakers have squeezed more computing power out of silicon by shrinking transistors, but that strategy is ...

As the industry advances into the angstrom era, gate-all-around architectures combined with atomic-scale materials engineering provide a sustainable path forward. The demands of AI and edge computing ...

Cornell engineers have built a next-gen transistor on bulk aluminum nitride that runs cooler, handles higher power, and ...