Co-design Center for Quantum Advantage and Quantum Systems Accelerator are funded by the U.S. Department of Energy to accelerate the development of quantum computers.
IAIFI will advance physics knowledge — from the smallest building blocks of nature to the largest structures in the universe — and galvanize AI research innovation.
“Qubit by Qubit” introduces high school students to quantum computing through a week-long summer camp and a year-long course.
Researchers devise an on-off system that allows high-fidelity operations and interconnection between processors.
Eight faculty members have been granted tenure in five departments across the School of Engineering.
MIT researchers develop integrated lightwave electronic circuits to detect the phase of ultrafast optical fields.
Magnetic nanodiscs can be activated by an external magnetic field, providing a research tool for studying neural responses.
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.
Method could shed light on nitric oxide’s role in the neural, circulatory, and immune systems.
New roll-to-roll production method could enable lightweight, flexible solar devices and a new generation of display screens.
Technique paves the way for more energy efficient, 3D microprocessors.
“Gold standard” material for generating oxygen from water divulges its molecular mechanisms.
Using magnetic nanoparticles, scientists stimulate the adrenal gland in rodents to control release of hormones linked to stress.
Technique may enable molecule-based quantum computing.