How ultracold, superdense atoms become invisible
A new study confirms that as atoms are chilled and squeezed to extremes, their ability to scatter light is suppressed.
A new study confirms that as atoms are chilled and squeezed to extremes, their ability to scatter light is suppressed.
SMART researchers demonstrate a practical way to make indium gallium nitride LEDs with considerably higher indium concentration.
Professor Nicholas Fang’s startup Boston Micro Fabrication uses a novel light-focusing method to make ultraprecise printers.
SMART findings allow a new way to control light emitting from materials.
Design of miniature optical systems could lead to future cell phones that can detect viruses and more.
“Programmable matter” technique could enable product designers to churn out prototypes with ease.
MIT researchers develop compact on-chip device for detecting electric-field waveforms with attosecond time resolution.
The findings pave the way to develop more efficient next-gen LEDs that cover the entire visible spectrum.
The design may enable miniature zoom lenses for drones, cellphones, or night-vision goggles.
The design, which uses entangled atoms, could help scientists detect dark matter and study gravity’s effect on time.
The findings may help researchers design “spintronic” devices and novel magnetic materials.
The results should help scientists study the viscosity in neutron stars, the plasma of the early universe, and other strongly interacting fluids.
The single piece of glass produces crisp panoramic images.
With funding from MISTI, physicists at MIT and in Israel collaborate to improve understanding and use of quantum light.
“Light squeezer” reduces quantum noise in lasers, could enhance quantum computing and gravitational-wave detection.