Converting Wi-Fi signals to electricity with new 2-D materials
Device made from flexible, inexpensive materials could power large-area electronics, wearables, medical devices, and more.
Device made from flexible, inexpensive materials could power large-area electronics, wearables, medical devices, and more.
William Oliver says a lack of available quantum scientists and engineers may be an inhibitor of the technology’s growth.
Theoretical analysis distinguishes observed “holes” from the huge list of hypothetically possible ones.
Computer program can translate a free-form 2-D drawing into a DNA structure.
MIT researchers show how to make and drive nanoscale magnetic quasi-particles known as skyrmions for spintronic memory devices.
First measurement of its kind could provide stepping stone to practical quantum computing.
Faculty researchers share insights into new capabilities at the annual Industrial Liaison Program Research and Development Conference.
It’s not quite the Ant-Man suit, but the system produces 3-D structures one thousandth the size of the originals.
Process that modifies semiconductor material atom by atom could enable higher-performance electronics.
High-speed camera shows incoming particles cause damage by briefly melting surfaces as they strike.
In MIT visit, BP chemist details new X-ray and sample chamber technologies, yielding insights into fighting metal corrosion, improving catalytic reactions, and more.
Detailed 3-D imaging of kerogen, a source of petroleum and natural gas, could improve estimates of recoverable amounts.
Innovative approach to controlling magnetism could lead to next-generation memory and logic devices.
At the Materials Day Symposium, researchers focus on tools that probe atomic structures in action to yield better designs for metals, solar cells, and polymers.