Haystack research scientist speaks with Lowell Sun reporter Alana Melanson about how scientists at the Haystack Observatory made key contributions to creating the first-ever image of a black hole. “It's enormous volumes of data coming at you very, very fast -- much faster than you can record on a single hard drive,” says Fish of the vast quantities of data processed at Haystack to develop the image.
WCVB-TV’s Rhondella Richardson visits the MIT Haystack Observatory to learn more about how researchers there helped process the data that was compiled to produce the first image of a black hole. “It really does look exactly like what we expected it to, based on Einstein’s model of relativity,” explains Michael Hecht, Haystack’s associate director for research management. “There’s still a sense of awe.”
Science News reporter Maria Temming speaks with researchers from the Event Horizon Telescope about their work capturing the first picture of a black hole. Describing how the image was captured, Haystack research scientist Vincent Fish explains that the team was able to “reconstruct images, even though we don’t have 100 percent of the information, is because we know what images look like” in general.
Haystack postdoc Kazunori Akiyama speaks with Gizmodo reporter Ryan Mandelbaum about the effort to capture the first image of a black hole, and notes that in the future, additional observations should shed light on how the region around the black hole is changing. “By accumulating observations over the next year with additional telescopes, we can identify what’s changing the black hole image,” Akiyama explains.
Fortune reporter Chris Morris explores how the Event Horizon Telescope has captured the first image of a black hole. “We’ve demonstrated that the EHT is the observatory to see a black hole on an event horizon scale,” says Haystack postdoc Kazunori Akiyama. “This is the dawn of a new era of black hole astrophysics.”
WBZ-TV’s Ken MacLeod visits MIT’s Haystack Observatory to learn about how scientists there processed enormous quantities of data to develop the first image of a black hole. “My goodness, we just proved that Einstein was right at a scale that no one has dreamed of,” says Haystack’s Michael Hecht. “Most of us still don’t believe it’s possible, even though we have done it.”
MassLive reporter Kristin LaFratta spotlights how researchers from the MIT Haystack Observatory played a key role in processing the first image of a black hole. “This project has been my life ever since the beginning of it. It’s overwhelming,” says Haystack’s Michael Titus. “It’s something that’s been a long time coming.”
Haystack research scientist Vincent Fish speaks with Radio Boston about the significance of capturing the first image of a black hole. “It seemed like it would take forever for us to constitute an array to actually be able to make an image,” recalls Fish of the early days of the project. “Actually making an image, I’m glad to be able to do that.”
Boston Globe reporter Martin Finucane spotlights how MIT Haystack Observatory researchers played a “major role in the effort to create the first-ever picture of a black hole.” “I’m very proud,” says Vincent Fish, a research scientist at Haystack. “I’ve spent most of my professional life on this and I’m just really glad we got such great results out of this.”
In this video, Mashable spotlights how MIT researchers have developed an origami-inspired soft robotic gripper that can grasp a wide variety of objects.
Fast Company reporter Mark Wilson writes that CSAIL researchers have developed a new soft robotic gripper that is modeled after a Venus flytrap. “Dubbed the Magic Ball, it’s a rubber and plastic structure that can contract around an object like an origami flower,” Wilson explains.
CSAIL researchers have developed a new robotic gripper that contains an origami skeleton, enabling the device to open and close like a flower and grasp a variety of delicate and heavy objects, reports James Vincent for The Verge “By combining this foldable skeleton with the soft exterior, we get the best of both worlds,” explains Prof. Daniela Rus, director of CSAIL.
MIT researchers have developed a new drug-releasing coil that could be used to help treat tuberculosis, reports Ruby Prosser Scully for New Scientist. Scully explains that the coil is “too large to leave the stomach, so it stays there, and the medicines threaded onto it leach out at a rate depending on the type of drug and the polymer the developers use to make the pills.”
TechCrunch reporter Brian Heater writes that researchers at CSAIL and Harvard have developed a soft robotic gripper that can both handle delicate objects and lift items up to 100 times its own weight. “The gripper itself is made of an origami-inspired skeletal structure, covered in either fabric or a deflated balloon,” explains Heater.
Financial Times reporter Clive Cookson writes that researchers from MIT and Penn State have developed a technique to make clear droplets produce iridescent colors. Cookson explains that the phenomenon is a previously unknown example of ‘structural color,’ produced not by pigments but the internal reflections of light within the tiny droplets.”