Nuclear fusion is often described as the holy grail of clean energy: a process that could one day provide abundant power without carbon emissions or long-lived radioactive waste. It has so much promise, but it's difficult. This article on fusion explains why. But turning fusion into a practical energy source depends on solving a set of extremely difficult physics problems. One of the most important is how to keep plasma — a super-hot, electrically charged gas — dense, stable, and confined long enough to produce useful energy.
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“We have the chance to explore new forms of storytelling about energy,” adds Italo Rota, co-designer of the installation. “We believe that design is a powerful tool to turn a narration into an experience, allowing visitors to sense the energy while being surrounded by a unique atmosphere.”
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The PPA further validates that CFS is on the most promising path to deliver commercial fusion power in the coming years. The company has demonstrated its capabilities by developing key advances in high-temperature superconducting magnets and sustaining its execution velocity in the construction of the SPARC fusion demonstration machine in Devens, Massachusetts.
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Helion’s model plays to America's old strength: innovation through agility, not top-down megaprojects. Instead of waiting for 2050, Helion’s compact reactors aim to deliver electricity in a matter of years—and not just for cities, but for data centers, isolated industries, military bases, even disaster zones. Their current prototype, Polaris, is scheduled to fire in 2025. If Helion succeeds, it won’t just disrupt global energy. It could redraw the world map.
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LLNL showed that a laser confinement fusion power is possible even if it isn’t practical until it can target its lasers at more than one peppercorn for longer than a ten-billionth of a second.
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