Portable system boosts laser precision, at room temperature
“Light squeezer” reduces quantum noise in lasers, could enhance quantum computing and gravitational-wave detection.
“Light squeezer” reduces quantum noise in lasers, could enhance quantum computing and gravitational-wave detection.
Study shows LIGO’s 40-kilogram mirrors can move in response to tiny quantum effects, revealing the “spooky popcorn of the universe.”
Neptune-sized planet may be remnant core of a much larger planet.
Signal from 500 million light years away is the first periodic pattern of radio bursts detected.
Danielle Frostig, a physics graduate student, is developing an instrument to study how the heaviest elements in the universe are produced.
Discovery made through the Disk Detective project could help the search for new planets.
When searching for extraterrestrial life, astronomers may want to look at planets with hydrogen-rich atmospheres.
Ten staff members recognized for dedication to School of Science and to MIT.
Michael Calzadilla and colleagues describe a violent black hole outburst that provides new insight into galaxy cluster evolution.
A molecule that’s known for its smelly and poisonous nature on Earth may be a sure-fire sign of extraterrestrial life.
Technology “squeezes” out quantum noise so more gravitational wave signals can be detected.
With increasingly advanced data, Michael McDonald and colleagues study a galaxy cluster bursting with new stars.
MIT Kavli Institute researcher working on the TESS mission gave the keynote address at an annual event organized by the Lincoln Laboratory Hispanic/Latino Network.
Those selected for these positions receive additional support to pursue their research and develop their careers.
New lens technique spots tiny dwarf galaxy in the first, super-energetic stages of star formation.