Discovery suggests new promise for nonsilicon computer transistors
Once deemed suitable only for high-speed communication systems, an alloy called InGaAs might one day rival silicon in high-performance computing.
Once deemed suitable only for high-speed communication systems, an alloy called InGaAs might one day rival silicon in high-performance computing.
Fabric samples are headed to the International Space Station for resiliency testing; possible applications include cosmic dust detectors or spacesuit smart skins.
In a new realm of materials, PhD student Thanh Nguyen uses neutrons to hunt for exotic properties that could power real-world applications.
The instrument could bring powerful sensing and imaging capabilities out of the lab and into hospitals, airports, or other settings.
MorphSensor lets users digitally model an object’s form and electronic function in one integrated space.
Building quantum computers underground or designing radiation-proof qubits may be needed, researchers find.
Everactive provides an industrial “internet of things” platform built on its battery-free sensors.
MIT researchers develop integrated lightwave electronic circuits to detect the phase of ultrafast optical fields.
MIT engineers develop a hybrid process that connects photonics with “artificial atoms,” to produce the largest quantum chip of its type.
Juejun Hu pushes the frontiers of optoelectronics for biological imaging, communications, and consumer electronics.
Fabrication technique will enable SkyWater Technology to manufacture a range of electronics that can withstand harsh radiation environments.
Exotic states called Kohn anomalies could offer clues to why some materials have the electronic properties they do.
The design could advance the development of small, portable AI devices.
Technique paves the way for more energy efficient, 3D microprocessors.
Soon, your clothes may be able to monitor your vital signs, analyze the results, and warn you of health risks.