Milestones in fusion experiments Early experiments The first machine to achieve controlled
thermonuclear fusion was a
pinch machine at Los Alamos National Laboratory called Scylla I at the start of 1958. The team that achieved it was led by a British scientist named
James Tuck and included a young
Marshall Rosenbluth. Tuck had been involved in the Manhattan project, but had switched to working on fusion in the early 1950s. He applied for funding for the project as part of a White House sponsored contest to develop a fusion reactor along with
Lyman Spitzer. The previous year, 1957, the British had claimed that they had achieved thermonuclear fusion reactions on the
Zeta pinch machine. However, it turned out that the neutrons they had detected were from beam-target interactions, not fusion, and they withdrew the claim. A
CERN-sponsored study group on controlled thermonuclear fusion met from 1958 to 1964. This group ceased when it became clear that CERN discontinued its limited support for plasma physics. Scylla I was a classified machine at the time, so the achievement was hidden from the public. A traditional
Z-pinch passes a current down the center of a plasma, which makes a magnetic force around the outside which squeezes the plasma to fusion conditions. Scylla I was a
θ-pinch, which used deuterium to pass a current around the outside of its cylinder to create a magnetic force in the center.
First tokamak In the early 1950s, Soviet physicists
I.E. Tamm and
A.D. Sakharov developed the concept of the tokamak, combining a low-power pinch device with a low-power stellarator.:90 Over time, the "advanced tokamak" concept emerged, which included non-circular plasma, internal diverters and limiters, superconducting magnets, operation in the "H-mode" island of increased stability, and the compact tokamak, with the magnets on the inside of the vacuum chamber.
First inertial confinement experiments Laser fusion was suggested in 1962 by scientists at
Lawrence Livermore National Laboratory (LLNL), shortly after the invention of the laser in 1960.
Inertial confinement fusion experiments using lasers began as early as 1965. Several laser systems were built at LLNL, including the
Argus, the
Cyclops, the
Janus, the
long path, the
Shiva laser, and the
Nova. Laser advances included frequency-tripling crystals that transformed infrared laser beams into ultraviolet beams and "chirping", which changed a single wavelength into a full spectrum that could be amplified and then reconstituted into one frequency. Laser research cost over one billion dollars in the 1980s.
1980s The
PLT,
TFTR,
Tore Supra,
JET,
T-15, and
JT-60 tokamaks were built and operated in the 1980s. In 1984, Martin Peng of ORNL proposed the
spherical tokamak with a much smaller radius. It used a single large conductor in the center, with magnets as half-rings off this conductor. The aspect ratio fell to as low as 1.2.:B247:225 Peng's advocacy caught the interest of
Derek Robinson, who built the
Small Tight Aspect Ratio Tokamak, (START). In 1993, TFTR became the first tokamak to conduct experiments with significant mixes of deuterium and tritium. In 1994 these experiments resulted in a discharge with the world record 10.1 MW fusion power with 39.9 MW of neutral beam heating power. The ratio Q is 0.26. The ratio in the plasma core, Q was approximately 0.8. In 1996, Tore Supra created a plasma for two minutes with a current of almost 1 million amperes, totaling 280 MJ of injected and extracted energy. In 1997, JET produced a peak of 16.1 MW of fusion power (65% of heat to plasma), with fusion power of over 10 MW sustained for over 0.5 sec.
2000s became operational in the UK in 1999. "Fast ignition" saved power and moved ICF into the race for energy production. In 2006, China's
Experimental Advanced Superconducting Tokamak (EAST) test reactor was completed. It was the first tokamak to use superconducting magnets to generate both toroidal and poloidal fields. In March 2009, the laser-driven ICF
NIF became operational. In the 2000s, privately backed fusion companies entered the race, including
TAE Technologies,
General Fusion, and
Tokamak Energy.
2010s Private and public research accelerated in the 2010s. General Fusion developed plasma injector technology and Tri Alpha Energy tested its C-2U device. The French
Laser Mégajoule began operation. NIF achieved net energy gain in 2013, as defined in the very limited sense as the hot spot at the core of the collapsed target, rather than the whole target. In 2014,
Phoenix Nuclear Labs sold a high-yield
neutron generator that could sustain 5×1011
deuterium fusion reactions per second over a 24-hour period. In 2015,
MIT announced a
tokamak it named the
ARC fusion reactor, using
rare-earth barium-copper oxide (REBCO) superconducting tapes to produce high-magnetic field coils that it claimed could produce comparable magnetic field strength in a smaller configuration than other designs. In October, researchers at the
Max Planck Institute of Plasma Physics in Greifswald, Germany, completed building the largest
stellarator to date, the
Wendelstein 7-X (W7-X). The W7-X stellarator began Operational phase 1 (OP1.1) on December 10, 2015, successfully producing helium plasma. The objective was to test vital systems and understand the machine's physics. By February 2016, hydrogen plasma was achieved, with temperatures reaching up to 100 million Kelvin. The initial tests used five graphite limiters. After over 2,000 pulses and achieving significant milestones, OP1.1 concluded on March 10, 2016. An upgrade followed, and OP1.2 in 2017 aimed to test an uncooled divertor. By June 2018, record temperatures were reached. W7-X concluded its first campaigns with limiter and island divertor tests, achieving notable advancements by the end of 2018. It soon produced helium and hydrogen plasmas lasting up to 30 minutes. The UK's Tokamak Energy's
ST40 generated "first plasma". The next year,
Eni announced a $50 million investment in
Commonwealth Fusion Systems, to attempt to commercialize MIT's
ARC technology.
2020s In January 2021, SuperOx announced the commercialization of a new
superconducting wire with more than 700 A/mm2 current capability. TAE Technologies announced results for its Norman device, holding a temperature of about 60 MK for 30 milliseconds, 8 and 10 times higher, respectively, than the company's previous devices. In October, Oxford-based
First Light Fusion revealed its projectile fusion project, which fires an aluminum disc at a fusion target, accelerated by a 9 mega-amp electrical pulse, reaching speeds of . The resulting fusion generates neutrons whose energy is captured as heat. On November 8, in an invited talk to the 63rd Annual Meeting of the APS Division of Plasma Physics, the National Ignition Facility claimed while Commonwealth Fusion Systems raised an additional $1.8 billion in Series B funding to construct and operate its
SPARC tokamak, the single largest investment in any private fusion company. In April 2022, First Light announced that their hypersonic projectile fusion prototype had produced neutrons compatible with fusion. Their technique electromagnetically fires projectiles at
Mach 19 at a caged fuel pellet. The deuterium fuel is compressed at Mach 204, reaching pressure levels of 100 TPa. On December 13, 2022, the
US Department of Energy reported that researchers at the National Ignition Facility had achieved a net energy gain from a fusion reaction. The reaction of hydrogen fuel at the facility produced about 3.15 MJ of energy while consuming 2.05 MJ of input. However, while the fusion reactions may have produced more than 3 megajoules of energy—more than was delivered to the target—NIF's 192 lasers consumed 322 MJ of grid energy in the conversion process. In May 2023, the
United States Department of Energy (DOE) provided a grant of $46 million to eight companies across seven states to support fusion power plant design and research efforts. This funding, under the Milestone-Based Fusion Development Program, aligns with objectives to demonstrate pilot-scale fusion within a decade and to develop fusion as a carbon-neutral energy source by 2050. The granted companies are tasked with addressing the scientific and technical challenges to create viable fusion pilot plant designs in the next 5–10 years. The recipient firms include
Commonwealth Fusion Systems, Focused Energy Inc., Princeton Stellarators Inc., Realta Fusion Inc., Tokamak Energy Inc., Type One Energy Group, Xcimer Energy Inc., and Zap Energy Inc. In December 2023, the largest and most advanced tokamak JT-60SA was inaugurated in
Naka, Japan. The reactor is a joint project between Japan and the European Union. The reactor had achieved its first plasma in October 2023. Subsequently, South Korea's fusion reactor project, the
Korean Superconducting Tokamak Advanced Research, successfully operated for 102 seconds in a high-containment mode (H-mode) containing high ion temperatures of more than 100 million degrees in plasma tests conducted from December 2023 to February 2024. In January 2025, EAST fusion reactor in China was reported to maintain a steady-state high-confinement plasma operation for 1066 seconds (nearly 18 minutes). In February 2025, the French Alternative Energies and Atomic Energy Commission (CEA) announced that its
WEST tokamak had maintained a stable plasma for 1,337 seconds—over 22 minutes. In March Energy Singularity announced that a magnet that produce a magnetic field of 21.7
T. In 2026, EAST announced that it had surpassed the Greenwald plasma density limit. The experiment pioneered plasma-wall self-organization, electron cyclotron resonance heating (ohmic start-up), management of initial fuel gas pressure, active reduction of boundary impurity sputtering and contamination from the reactor walls. The plasma entered a density-free regime where higher density did not increase instability. ==Future development==