![]() ![]() "That's very ambitious, but that's the target we're working toward," Greenwald said. Once researchers have built and tested SPARC, they plan to construct the ARC (Affordable Robust Compact) reactor, which would generate electricity from that heat by 2035. SPARC would only produce heat, not electricity. "In the current power market of the United States, power plants typically generate between 100 to 500 megawatts," Greenwald said. The researchers ultimately hope SPARC-inspired fusion power plants would generate between 250 to 1,000 megawatts of electricity. In contrast, renewable energy sources such as solar and wind "are not accommodated well by the current design of electric grids." "Fusion power plants could be one-to-one replacements for fossil fuel plants, and you wouldn't have to restructure electrical grids for them," Greenwald said. This steam would then drive a turbine and electrical generator, the same way most electricity is produced nowadays. The heat from a fusion reactor would generate steam. SPARC is expected to generate at least twice as much as 10 times more energy as is pumped in, the studies found. In seven new studies, researchers outlined the calculations and supercomputer simulations underlying SPARC's design. "That dramatic reduction in size is accompanied by a reduction in weight and cost," Greenwald, told LiveScience. These powerful magnets suggest the core of SPARC can be about three times smaller in diameter, and 60 to 70 times smaller in volume than the heart of ITER, which is slated to be 6 meters wide. (In comparison, Earth's magnetic field ranges in strength from 30 millionths to 60 millionths of a tesla.) These new magnets can produce far more powerful magnetic fields than ITER's - a maximum of 21 teslas, compared with ITER's maximum of 12 teslas. SPARC will use so-called high-temperature superconducting magnets that only became commercially available in the past three to five years, long after ITER was first designed. One advantage that SPARC may have over ITER is that SPARC's magnets are designed to confine its plasma. This is far faster than the world's largest fusion power project, known as the International Thermonuclear Experimental Reactor (ITER), which was conceived in 1985 but not launched until 2007 and although construction began in 2013, the project is not expected to generate a fusion reaction until 2035. The SPARC project, which launched in 2018, is scheduled to begin construction next June, with the reactor starting operations in 2025. But no one has ever been able to harness the power of burning plasma in a controlled reaction here on Earth, and more research is needed before SPARC can do so. If it succeeds, SPARC would be the first device to ever achieve a "burning plasma," in which the heat from all the fusion reactions keeps fusion going without the need to pump in extra energy. Photos: Inside the world's top physics labs What's that? Your physics questions answered The biggest unsolved mysteries in physics The new experimental device, called the SPARC (Soonest/Smallest Private-Funded Affordable Robust Compact) reactor, is being developed by scientists at MIT and a spinoff company, Commonwealth Fusion Systems. These designs use powerful magnetic fields to confine a cloud of plasma, or ionized gas, at extreme temperatures, high enough for atoms to fuse together. ![]() Most experimental fusion reactors employ a donut-shaped Russian design called a tokamak. ![]() We need a solution for global warming - otherwise, civilization is in trouble. "Virtually all of us got into this research because we're trying to solve a really serious global problem," said study author Martin Greenwald, a plasma physicist at MIT and one of the lead scientists developing the new reactor. And the fuel for fusion - such as the element hydrogen - is plentiful enough on Earth to meet all of humanity's energy needs for millions of years. At the same time, fusion doesn't produce greenhouse gases such as carbon dioxide, which drive global warming, nor does it generate other pollutants. However, such reactions can generate far more energy than they require. But an enormous amount of energy is needed to force atoms to fuse together, which occurs at temperatures of at least 180 million degrees Fahrenheit (100 million degrees Celsius). ![]()
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