Engineers report a major advance in creating a new family of semiconductor materials
Ultrastable and made of inexpensive, nontoxic elements, chalcogenide perovskites could find applications in solar cells, lighting, and more.
Ultrastable and made of inexpensive, nontoxic elements, chalcogenide perovskites could find applications in solar cells, lighting, and more.
Current and former MIT researchers find novel tools can improve the sustainability of road networks on a limited budget.
Reversible system can flip the magnetic orientation of particles with a small voltage; could lead to faster data storage and smaller sensors.
MIT researchers find emissions of U.S. buildings and pavements can be reduced by around 50 percent even as concrete use increases.
New property in an ultrathin cousin of graphene could allow for much denser computer memory.
How-to manual from MIT and the Fashion Institute of Technology codifies successful textiles partnership between designers, engineers.
Two research projects on the design of state-of-the-art hardware could one day power next-generation 5G and 6G mobile networks.
A scattering-type scanning nearfield optical microscope offers advantages to researchers across many disciplines.
First experimental evidence of spin excitations in an atomically thin material helps answer 30-year-old questions, could lead to better medical diagnostics and more.
Work on three graphene-based devices may yield new insights into superconductivity.
The findings could lead to faster, more secure memory storage, in the form of antiferromagnetic bits.
Design of miniature optical systems could lead to future cell phones that can detect viruses and more.
A new framework calculates companies’ beneficial environmental "handprints" as well as their negative footprints, to encourage eco-friendly actions.
Cutting-edge microscope helps reveal ways to control the electronic properties of atomically thin materials.
Unconventional form of ferroelectricity could impact next-generation computing.