The Venus Life Finder (VLF) developed by scientists at MIT will be launched on a Rocket lab Electronic in May of 2023 to search for life in the upper atmosphere of Venus, reports Mark R. Whittington for The Hill. “When it plunges into Venus’ atmosphere it will use an instrument called the ‘autofluorescing nephelometer’ that will use a laser to illuminate organic molecules that may or may not exist 50 kilometers above the planet’s surface,” writes Whittington.
Prof. Julien de Wit speaks with Newsweek reporter Ed Browne about the wealth of information that the James Webb telescope will be providing about the universe. "In terms of information content, we're pretty much going from listening to the radio, to having television," said de Wit.
Scientists from MIT and other institutions have detected the longest-lasting and most regular radio signal in the night sky, reports Jamie Carter for Forbes. “Scientists think that the radio signal may be coming from a neutron star—what remains of the collapsed core of a giant star after it’s exploded as a supernova,” explains Carter.
Astronomers from MIT and elsewhere have discovered radio signals in space that they believe to be coming from a neutron star, reports Tim Marcin for Mashable. “Using the CHIME (Canadian Hydrogen Intensity Mapping Experiment) radio telescope, astronomers noticed a strange FRB, or radio burst, from a far-off galaxy billions of light-years from Earth.”
Scientists from MIT and elsewhere have detected a series of fast radio bursts from a distant galaxy, reports Samantha Cole for Vice. “This detection raises the question of what could cause this extreme signal that we’ve never seen before, and how can we use this signal to study the universe,” says postdoctoral scholar Daniele Michilli. “Future telescopes promise to discover thousands of FRBs a month, and at that point we may find many more of these periodic signals.”
A team of astronomers have identified a mysterious radio burst from a far-away galaxy, reports Wyatte Grantham-Philips for USA Today. “Imagine a very distant galaxy. And sometimes, some huge explosions happen that emit huge blasts of radio waves,” explains Daniele Michilli, who led the study and is a postdoc in MIT’s Kavli Institute for Astrophysics and Space Research. “We don’t know what these explosions are, (but) they are so powerful that we can see them from across the universe.”
Postdoctoral scholar Daniele Michilli and members of the CHIME/FRB Collaboration have discovered radio bursts from a galaxy billions of light-years away, reports Ashley Strickland for CNN. “The research team will continue to use CHIME to monitor the skies for more signals from the radio burst, as well as others with a similar, periodic signal,” writes Strickland, noting the work “could be used to help astronomers learn more about the rate of the universe’s expansion.”
Astronomers at MIT and elsewhere have picked up repeated radio signals from a galaxy billions of light-years away from Earth, reports Ayana Archie for NPR. “Scientists have not been able to pinpoint the exact location of the radio waves yet, but suspect the source could be neutron stars, which are made from collapsed cores of giant stars,” writes Archie.
MIT researchers have created Thesan, the most detailed model of the early universe to date, reports New Scientist. “Thesan shows how radiation shaped the universe from 400,000 to 1 billion years after the Big Bang,” writes New Scientist.
Astronomers have identified two Earth-sized exoplanets orbiting a red dwarf star 33 light years away, reports Jamie Carter for Forbes. “Both planets in this system are each considered among the best targets for atmospheric study because of the brightness of their star,” explains postdoc Michelle Kunimoto.
Scientists from MIT and other institutions have developed the largest, most detailed computer model of the universe’s first billion years, which could help shed light on how the early universe evolved, reports Charles Q. Choi for Scientific American. The model, named THESAN, “can track the birth and evolution of hundreds of thousands of galaxies within a cubic volume spanning more than 300 million light-years across.”
Researchers at MIT have developed an automated search tool that can help astronomers identify the echoes emitted by a specific type of black hole, reports Juandre for Popular Mechanics. “The team’s algorithm, which they dubbed the ‘Reverberation Machine,’ pored through data collected by the Neutron Star Interior Composition Explorer, an x-ray telescope mounted to the International Space Station,” writes Juandre. “They identified previously undetected echoes from black hole binary systems in our galaxy.”
MIT astronomers have used light echoes from X-ray bursts to try to map the environment around black holes, reports Dennis Overbye for The New York Times. Prof. Erin Kara then worked with education and music experts to transform the X-ray reflections into audible sound. “I just love that we can ‘hear’ the general relativity in these simulations,” said Kara.
CNN reporter Ashley Strickland writes that MIT astronomers developed an automated search tool and were able to “pin down the locations of eight rare pairings of black holes and the stars orbiting them, thanks to the X-ray echoes they release.”
Vice reporter Becky Ferreira writes that MIT researchers developed a new system, called the Reverberation Machine, to detect the echoes from eight new echoing black hole binaries. “These echoes offer a rarely seen glimpse into the otherworldly surroundings of stellar-mass black holes, which are about five to 15 times the mass of the Sun,” writes Ferreira.