Newsweek reporter Tom Howarth spotlights MIT spinout Commonwealth Fusion Systems as they announced plans to “build the world's first grid-scale commercial nuclear fusion power plant” in Virginia. “The plant is expected to generate 400 megawatts of electricity, enough to power approximately 150,000 homes or large industrial facilities,” writes Howarth.
Commonwealth Fusion Systems, an MIT spinoff, plans to build “the nation’s first grid-scale fusion power plant in Virginia by the early 2030s,” reports Laura Vozzella and Gregory S. Schneider for The Washington Post. “Fusion is a long-sought source of power that can generate almost limitless energy by combining atomic nuclei,” they write. “It is unlike fission, the more common form of nuclear energy, in which the nucleus is split, and which generates large amounts of radioactive waste.”
MIT spinoff Commonwealth Fusion Systems has shared their plans “to build its first commercial power plant” in Virginia, reports Aaron Pressman for The Boston Globe. “Commonwealth aims to build a complete power plant with a fusion machine generating heat used to spin turbines and make 400 megawatts of electric power, enough to supply 150,000 homes, by the mid-2030s,” explains Pressman.
Commonwealth Fusion Systems, an MIT spinout, has announced plans to “build its first fusion power plant in Virginia, with the aim of generating zero-emissions electricity there in the early 2030s,” reports Raymond Zhong for The New York Times. “The proposed facility is among the first to be announced that would harness nuclear fusion, the process that powers the sun, to produce power commercially, a long-elusive goal that scientists have pursued for the better part of a century,” explains Zhong.
MIT spinout Commonwealth Fusion Systems has announced plans to build the “world’s first grid-scale fusion power plant in Virginia, to generate power by the early 2030s,” reports Timothy Gardner for Reuters. The project, “could revolutionize the global energy industry by tapping into a virtually limitless power source, similar to that which fuels the stars,” writes Gardner.
MIT researchers have analyzed tiny particles from a distant asteroid and found that a weak magnetic field may have helped form the outer planets in our solar system, reports Sabrina Lam for The Boston Globe. In the future, the researchers hope to use samples from other celestial bodies to identify magnetic fields in our universe. “An exciting thing that’s probably going to happen in the next few decades,” says Prof. Benjamin Weiss, “is that we’re going to start bringing samples back from comets.”
Researchers from MIT’s Plasma Science and Fusion Center and Commonwealth Fusion Systems (CFS) are using high-temperature superconducting tape as a key part of the design for their tokamak reactor, reports Tom Clynes for IEEE Spectrum. The researchers believe that “this novel approach will allow it to build a high-performance tokamak that is much smaller and less expensive than would be possible with previous approaches,” Clynes notes.
Researchers at MIT have developed a soft robot that can be controlled by a weak magnetic field and travel through tiny spaces within the human body, reports Andrew Paul for Popular Science. “Because of their soft materials and relatively simple manipulation, researchers believe such mechanisms could be used in biomedical situations, such as inching through human blood vessels to deliver a drug at a precise location,” explains Paul.
Darby Dunn ’08 speaks with CNBC reporter Catherine Clifford about her journey from building rockets for SpaceX to working on making fusion energy a reality at Commonwealth Fusion Systems (CFS). “For me, it really came down to wanting to use my energy to clean up the planet instead of get off it,” says Dunn. “So that was the huge shift for me to come to CFS.”
Commonwealth Fusion Systems, MIT’s Plasma Science and Fusion Center and others are working to build SPARC, a prototype device that aims to extract net energy from plasma and generate fusion power, reports Philip Ball for Scientific American. “SPARC will be a midsize tokamak in which the plasma is tightly confined by very intense magnetic fields produced by new high-temperature superconducting magnets developed at MIT and unveiled in 2021.”
Researchers from MIT and else have documented the destructive power of hand magnets, a technique used for identifying meteorites, reports Zack Savitsky for Science. “When brought within a few centimeters of a rock, the researchers found, the magnets overwrite vestigial fields contained in iron-based minerals such as magnetite and reset them to the higher strength and orientation of the magnet,” writes Savitsky.
Forbes has named Commonwealth Fusion Systems one of the biggest tech innovations and breakthroughs of 2022, reports Bernard Marr. “Commonwealth Fusion Systems is now working with MIT’s Plasma Science and Fusion Center on plans to build a factory that can mass-produce components for the first commercial fusion reactors,” writes Marr.
Researchers from MIT’s Plasma Science and Fusion Center (PSFC) and Commonwealth Fusion Systems (CFS) are working on making commercial nuclear fusion a reality, reports Juandre for Popular Mechanics. “CFS will build [the tokamak] SPARC and develop a commercial fusion product, while MIT PSFC will focus on its core mission of cutting-edge research and education,” says Prof. Dennis G. Whyte, director of the PSFC.
Financial Times reporter Tom Wilson writes that researchers from MIT and Commonwealth Fusion Systems (CFS) have successfully demonstrated the use of a high-temperature superconductor, which engineers believe can allow for a more compact fusion power plant. “It’s the type of technology innovation that you know shows up every once in a while in a given field,” CFS chief executive, Bob Mumgaard, tells Wilson.
Researchers at MIT’s Plasma Science and Fusion Center and Commonwealth Fusion Systems speak with The New Yorker’s Rivka Galchen about the history of fusion research and the recent test of their large high-temperature superconducting electromagnet. “I feel we proved the science. I feel we can make a difference,” says MIT alumna Joy Dunn, head of manufacturing at CFS. “When people ask me, ‘Why fusion? Why not other renewables,’ my thinking is: This is a solution at the scale of the problem.”