Tunable ultrasound propagation in microscale metamaterials
New framework advances experimental capabilities, including design and characterization, of microscale acoustic metamaterials.
New framework advances experimental capabilities, including design and characterization, of microscale acoustic metamaterials.
The startup SiPhox, founded by two former MIT researchers, has developed an integrated photonic chip for high-quality, home-based blood testing.
A new electrode design boosts the efficiency of electrochemical reactions that turn carbon dioxide into ethylene and other products.
At MIT, Keselman is a lecturer, executive director, managing director, and innovator. Additionally, he is a colonel in the Air Force Reserves, board director, and startup leader.
Researchers are leveraging quantum mechanical properties to overcome the limits of silicon semiconductor technology.
By snugly wrapping around neurons, these devices could help scientists probe subcellular regions of the brain, and might even help restore some brain function.
A new study of bubbles on electrode surfaces could help improve the efficiency of electrochemical processes that produce fuels, chemicals, and materials.
MIT and Lincoln Laboratory are among awardees of $38 million in project awards to the Northeast Microelectronics Coalition to boost U.S. chip technology innovation.
New STUDIO.nano supports artistic research and encounters within MIT.nano’s facilities.
For Sarah Sterling, the new director of the Cryo-Electron Microscopy facility at MIT.nano, better planning and more communication leads to better science.
Lightwave electronics aim to integrate optical and electronic systems at incredibly high speeds, leveraging the ultrafast oscillations of light fields.
A new family of integrated rock salt-polyanion cathodes opens door to low-cost, high-energy storage.
A trailblazer in electron microscopy, Vander Sande is remembered for his dedication to teaching, service, and global collaboration.
The new design approach could be used to produce metals with exceptional combinations of strength and ductility, for aerospace and other applications.
MIT.nano inscribes 340,000 names on a single silicon wafer in latest version of One.MIT.