Electrons become fractions of themselves in graphene, study finds
An exotic electronic state observed by MIT physicists could enable more robust forms of quantum computing.
An exotic electronic state observed by MIT physicists could enable more robust forms of quantum computing.
Thin flakes of graphite can be tuned to exhibit three important properties.
A newly discovered type of electronic behavior could help with packing more data into magnetic memory devices.
Flexible platform could produce enigmatic materials, lead to new studies of exotic phenomena.
Device for harnessing terahertz radiation might help power some portable electronics.
Next-generation devices made with new “peel and stack” method may include electronic chips worn on the skin.
Professor of physics honored alongside Allan MacDonald and Rafi Bistritzer for pioneering research on twisted bilayer graphene.
James Collins, Pablo Jarillo-Herrero, and Richard Milner have won top prizes for their work.
MIT Professor Frances Ross is pioneering new techniques to study materials growth and how structure relates to performance.
New method could be useful for building quantum sensors and computers.
Experiments and analyses show how electrons and protons get together on an electrode surface.
At relatively balmy temperatures, heat behaves like sound when moving through graphite, study reports.
Coating graphene with wax makes for a less contaminated surface during device manufacturing.
Theoretical analysis distinguishes observed “holes” from the huge list of hypothetically possible ones.
First measurement of its kind could provide stepping stone to practical quantum computing.