Physicists engineer ferroelectricity in boron nitride
New property in an ultrathin cousin of graphene could allow for much denser computer memory.
New property in an ultrathin cousin of graphene could allow for much denser computer memory.
MIT-led research team fashions graphene foam into device that can extract uranium and other heavy metals from tap water.
New findings might help inform the design of more powerful MRI machines or robust quantum computers.
Work on three graphene-based devices may yield new insights into superconductivity.
Cutting-edge microscope helps reveal ways to control the electronic properties of atomically thin materials.
Unconventional form of ferroelectricity could impact next-generation computing.
To oversee its new cutting-edge electron microscopy systems, MIT sought out Frances Ross’ industry-honed expertise.
Results could help designers engineer high-temperature superconductors and quantum computing devices.
Cornell University’s Paul McEuen will inaugurate series to honor beloved MIT professor.
Model could recreate video from motion-blurred images and “corner cameras,” may someday retrieve 3D data from 2D medical images.
Ultrathin coating could protect 2D materials from corrosion, enabling their use in optics and electronics.
MIT researchers discover why magnetism in certain materials is different in atomically thin layers and their bulk forms.
MIT Professor Frances Ross is pioneering new techniques to study materials growth and how structure relates to performance.
MIT researchers have demonstrated that a tungsten ditelluride-based transistor combines two different electronic states of matter.
Efficient method for making single-atom-thick, wafer-scale materials opens up opportunities in flexible electronics.