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  * NEWS
  * 15 December 2023
  * Correction 17 December 2023

US nuclear-fusion lab enters new era: achieving 'ignition' over and
over

Researchers at the National Ignition Facility are consistently
creating reactions that make more energy than they consume.

    By
  * Jeff Tollefson

 1. Jeff Tollefson
    View author publications

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NIF beamlines entering the lower hemisphere of the NIF Target
Chamber, as seen from the ground floor of the Target Bay.

At the US National Ignition Facility, in Livermore, California, 192
lasers (beamlines shown here) run into a target chamber (highlighted
in blue) and focus on a capsule containing hydrogen isotopes. Credit:
Damien Jemison/NIF/LLNL

In December 2022, after more than a decade of effort and frustration,
scientists at the US National Ignition Facility (NIF) announced that
they had set a world record by producing a fusion reaction that
released more energy than it consumed -- a phenomenon known as
ignition. They have now proved that the feat was no accident by
replicating it again and again, and the administration of US
President Joe Biden is looking to build on this success by
establishing a trio of US research centres to help advance the
science.

[d41586-023]

Nuclear-fusion breakthrough: this physicist helped to achieve the
first-ever energy gain

The stadium-sized laser facility, housed at the Lawrence Livermore
National Laboratory (LLNL) in California, has unequivocally achieved
its goal of ignition in four out of its last six attempts, creating a
reaction that generates pressures and temperatures greater than those
that occur inside the Sun.

"I'm feeling pretty good," says Richard Town, a physicist who heads
the lab's inertial-confinement fusion science programme at the LLNL.
"I think we should all be proud of the achievement."

The NIF was designed not as a power plant, but as a facility to
recreate and study the reactions that occur during thermonuclear
detonations after the United States halted underground weapons
testing in 1992. The higher fusion yields are already being used to
advance nuclear-weapons research, and have also fuelled enthusiasm
about fusion as a limitless source of clean energy. US secretary of
state John Kerry called for new international partnerships to advance
fusion energy at the COP28 climate summit in Dubai last week, and the
US Department of Energy (DOE), which oversees the NIF, followed up by
announcing the new research hubs, to be led by Lawrence Livermore,
the University of Rochester in New York and Colorado State University
in Fort Collins.

Building the NIF was "a leap of faith" for many, and its success has
had a real impact on the fusion community, as well as on public
perception, says Saskia Mordijck, a physicist at William & Mary, a
university in Willamsburg, Virginia. "In that sense, what is
important is that scientists said they could do something, and then
they actually did do something."

Hot shots

The NIF works by firing 192 laser beams at a frozen pellet of the
hydrogen isotopes deuterium and tritium that is housed in a diamond
capsule suspended inside a gold cylinder. The resulting implosion
causes the isotopes to fuse, creating helium and copious quantities
of energy. On 5 December 2022, those fusion reactions for the first
time generated more energy -- roughly 54% more -- than the laser beams
delivered to the target.

The facility set a new record on 30 July when its beams delivered the
same amount of energy to the target -- 2.05 megajoules -- but, this
time, the implosion generated 3.88 megajoules of fusion energy, an
89% increase over the input energy. Scientists at the laboratory
achieved ignition during two further attempts in October (see 'A year
of progress'). And the laboratory's calculations suggest that two
others in June and September generated slightly more energy than the
lasers provided, but not enough to confirm ignition.

A year of progress: Timeline of 'ignition' experiments conducted by
the US National Ignition Facility since December 2022.

Source: Lawrence Livermore National Laboratory

For many scientists, the results confirm that the laboratory is now
operating in a new regime: researchers can repeatedly hit a goal
they've been chasing for more than a decade. Tiny variations in the
laser pulses or minor defects in the diamond capsule can still allow
energy to escape, making for an imperfect implosion, but the
scientists now better understand the main variables at play and how
to manipulate them.

"Even when we have these issues, we can still get more than a
megajoule of fusion energy, which is good," says Annie Kritcher, the
NIF's lead designer on this series of experiments.

New hubs

It's a long way from there to providing fusion energy to the power
grid, however, and the NIF, although currently home to the world's
largest laser, is not well-suited for that task. The facility's laser
system is enormously inefficient, and more than 99% of the energy
that goes into a single ignition attempt is lost before it can reach
the target.

Developing more efficient laser systems is one goal of the DOE's new
inertial-fusion-energy research programme. This month, the agency
announced US$42 million over four years to establish three new
research centres -- each involving a mix of national laboratories,
university researchers and industry partners -- that will work towards
this and other advances.

[d41586-023]

Nuclear-fusion lab achieves 'ignition': what does it mean?

This investment is the first coordinated effort to develop not just
the technologies, but also the workforce for a future laser-fusion
industry, says Carmen Menoni, a physicist who is heading up the hub
at Colorado State University.

So far, most government investments in fusion-energy research have
gone towards devices known as tokamaks, which use magnetic fields
inside a doughnut-shaped 'torus' to confine fusion reactions. This is
the approach under development at ITER, an international partnership
to build the world's largest fusion facility near
Saint-Paul-lez-Durance, France. Tokamaks have also been the focus of
many fusion investments in the private sector, but dozens of
companies are pursuing other approaches, such as laser fusion.

The timing for a dedicated laser-fusion programme is right, says
Menoni, and the decision to pursue it wouldn't have happened without
the NIF's recent success. "We now know it will work," she says. "What
will take time is to develop the technology to a level where we can
build a power plant."

Back at the NIF, Kritcher's latest series of experiments features a
7% boost in laser energy, which should, in theory, lead to even
larger yields. The first experiment in this series was one of the
successful ignitions, on 30 October. Although it didn't break the
record, an input of 2.2 megajoules of laser energy yielded an output
of 3.4 megajoules of fusion energy.

Kritcher chalks up the fact that it didn't break the record for
energy yield to growing pains with the new laser configuration, which
is designed to squeeze more energy into the same gold cylinder.
Before moving to a larger cylinder, Kritcher says her team is going
to focus on changes to the laser pulse that could produce a more
symmetrical implosion. "We've got four experiments next year," she
says. "Let's see."

doi: https://doi.org/10.1038/d41586-023-04045-8

Updates & Corrections

  * Correction 17 December 2023: An earlier version of this article
    incorrectly stated the name of William & Mary.

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Related Articles

  * [d41586-023] Nuclear-fusion breakthrough: this physicist helped
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