After generations of trying to produce the power of a star on Earth, a successful nuclear fusion ignition happened in the middle of a December night and was over in 20-billionths of a second.
That’s more than 100 billion times shorter than the Wright Brothers’ first, 12-second flight — but a brief, shining moment that could have even bigger implications for humanity.
But while the science teams at Lawrence Livermore National Laboratory are still buzzing over their Wright-Brothers moment, we only remember that name because their third flight stayed in the sky for 39 minutes.
The nuclear fusion reaction must be repeated, extended and scaled before the comparison sticks. And the race is on to make it work.
“But that’s what makes it so exciting, right?” lead scientist Tammy Ma told CNN. “The potential is so great for clean, abundant, limitless, affordable energy. It will be tough. It won’t be easy. But it’s worth doing.”
Ma’s office is a giant box of lasers the size of three football fields in the corner of a 7,000-acre lab in Livermore. Running across the soaring white ceilings are miles of square tubes holding 192 of the most energetic lasers in the world, all snaking toward a round room at the center.
The very middle of this target chamber becomes the hottest place in the solar system every time they run a fusion experiment, and it is covered with enough gleaming machinery that J.J. Abrams used it to portray the warp core of the USS Enterprise in “Stark Trek Into Darkness.”
With a legacy of delays and cost overruns, the National Ignition Facility was wryly nicknamed the “National Almost Ignition Facility,” or “NAIF,” by critics in Congress. If not for its work studying nuclear weaponry without the need for test explosions, the program might have lost funding years ago.
But now, for the first time since breaking ground in 1997, the National Ignition Facility can finally live up to its name. In December, 192 of the most energetic lasers in the world heated up a tiny pellet of hydrogen atoms with such force, they fused together to create helium and — most importantly — excess energy.
A little more than 2 megajoules of energy going into the target chamber became 3.15 megajoules coming out — a modest gain of around 50%, but enough to make history and allow scientists to call the experiment a true success.
The five attempts since have all failed to repeat it. READ MORE...
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