List of fusion experiments

Experiments directed toward developing fusion power are invariably done with dedicated machines which can be classified according to the principles they use to confine the plasma fuel and keep it hot.

Target chamber of the Shiva laser, used for inertial confinement fusion experiments from 1978 until decommissioned in 1981.
Plasma chamber of TFTR, used for magnetic confinement fusion experiments, which produced 11 MW of fusion power in 1994.

The major division is between magnetic confinement and inertial confinement. In magnetic confinement, the tendency of the hot plasma to expand is counteracted by the Lorentz force between currents in the plasma and magnetic fields produced by external coils. The particle densities tend to be in the range of 1018 to 1022 m−3 and the linear dimensions in the range of 0.1 to 10 m. The particle and energy confinement times may range from under a millisecond to over a second, but the configuration itself is often maintained through input of particles, energy, and current for times that are hundreds or thousands of times longer. Some concepts are capable of maintaining a plasma indefinitely.

In contrast, with inertial confinement, there is nothing to counteract the expansion of the plasma. The confinement time is simply the time it takes the plasma pressure to overcome the inertia of the particles, hence the name. The densities tend to be in the range of 1031 to 1033 m−3 and the plasma radius in the range of 1 to 100 micrometers. These conditions are obtained by irradiating a millimeter-sized solid pellet with a nanosecond laser or ion pulse. The outer layer of the pellet is ablated, providing a reaction force that compresses the central 10% of the fuel by a factor of 10 or 20 to 103 or 104 times solid density. These microplasmas disperse in a time measured in nanoseconds. For a fusion power reactor, a repetition rate of several per second will be needed.

Magnetic confinement

Within the field of magnetic confinement experiments, there is a basic division between toroidal and open magnetic field topologies. Generally speaking, it is easier to contain a plasma in the direction perpendicular to the field than parallel to it. Parallel confinement can be solved either by bending the field lines back on themselves into circles or, more commonly, toroidal surfaces, or by constricting the bundle of field lines at both ends, which causes some of the particles to be reflected by the mirror effect. The toroidal geometries can be further subdivided according to whether the machine itself has a toroidal geometry, i.e., a solid core through the center of the plasma. The alternative is to dispense with a solid core and rely on currents in the plasma to produce the toroidal field.

Mirror machines have advantages in a simpler geometry and a better potential for direct conversion of particle energy to electricity. They generally require higher magnetic fields than toroidal machines, but the biggest problem has turned out to be confinement. For good confinement there must be more particles moving perpendicular to the field than there are moving parallel to the field. Such a non-Maxwellian velocity distribution is, however, very difficult to maintain and energetically costly.

The mirrors' advantage of simple machine geometry is maintained in machines which produce compact toroids, but there are potential disadvantages for stability in not having a central conductor and there is generally less possibility to control (and thereby optimize) the magnetic geometry. Compact toroid concepts are generally less well developed than those of toroidal machines. While this does not necessarily mean that they cannot work better than mainstream concepts, the uncertainty involved is much greater.

Somewhat in a class by itself is the Z-pinch, which has circular field lines. This was one of the first concepts tried, but it did not prove very successful. Furthermore, there was never a convincing concept for turning the pulsed machine requiring electrodes into a practical reactor.

The dense plasma focus is a controversial and "non-mainstream" device that relies on currents in the plasma to produce a toroid. It is a pulsed device that depends on a plasma that is not in equilibrium and has the potential for direct conversion of particle energy to electricity. Experiments are ongoing to test relatively new theories to determine if the device has a future.

Toroidal machine

Toroidal machines can be axially symmetric, like the tokamak and the reversed field pinch (RFP), or asymmetric, like the stellarator. The additional degree of freedom gained by giving up toroidal symmetry might ultimately be usable to produce better confinement, but the cost is complexity in the engineering, the theory, and the experimental diagnostics. Stellarators typically have a periodicity, e.g. a fivefold rotational symmetry. The RFP, despite some theoretical advantages such as a low magnetic field at the coils, has not proven very successful.

Tokamak
Device NameStatusConstructionOperationLocationOrganisationMajor/Minor RadiusB-fieldPlasma currentPurposeImage
T-1Shut down?1957-1959Moscow Kurchatov Institute0.625 m/0.13 m1 T0.04 MAFirst tokamak
T-3Shut down?1962-?Moscow Kurchatov Institute1 m/0.12 m2.5 T0.06 MA
ST (Symmetric Tokamak)Shut downModel C1970-1974Princeton Princeton Plasma Physics Laboratory1.09 m/0.13 m5.0 T0.13 MAFirst American tokamak, converted from Model C stellarator
ORMAK (Oak Ridge tokaMAK)Shut down1971-1976Oak Ridge Oak Ridge National Laboratory0.8 m/0.23 m2.5 T0.34 MAFirst to achieve 20 MK plasma temperature
ATC (Adiabatic Toroidal Compressor)Shut down1971-19721972-1976Princeton Princeton Plasma Physics Laboratory0.88 m/0.11 m2 T0.05 MADemonstrate compressional plasma heating
TFR (Tokamak de Fontenay-aux-Roses)Shut down1973-1984Fontenay-aux-Roses CEA1 m/0.2 m6 T0.49
T-10 (Tokamak-10)Shut down1975-?Moscow Kurchatov Institute1.50 m/0.36 m4 T0.6 MALargest tokamak of its time
PLT (Princeton Large Torus)Shut down1975-1986Princeton Princeton Plasma Physics Laboratory1.32 m/0.4 m4 T0.7 MAFirst to achieve 1 MA plasma current
ISX-BShut down?1978-?Oak Ridge Oak Ridge National Laboratory0.93 m/0.27 m1.8 T0.2 MASuperconducting coils, attempt high-beta operation
ASDEX (Axially Symmetric Divertor Experiment)[1]Recycled →HL-2A1980-1990Garching Max-Planck-Institut für Plasmaphysik1.65 m/0.4 m2.8 T0.5 MADiscovery of the H-mode in 1982
TEXTOR (Tokamak Experiment for Technology Oriented Research)[2][3]Shut down1976-19801981-2013Jülich Forschungszentrum Jülich1.75 m/0.47 m2.8 T0.8 MAStudy plasma-wall interactions
TFTR (Tokamak Fusion Test Reactor)[4]Shut down1980-19821982-1997Princeton Princeton Plasma Physics Laboratory2.4 m/0.8 m6 T3 MAAttempted scientific break-even, reached record fusion power of 10.7 MW and temperature of 510 MK
JET (Joint European Torus)[5]Operational1978-19831983-Culham Culham Centre for Fusion Energy2.96 m/0.96 m4 T7 MARecord for fusion output power 16.1 MW
Novillo[6][7]Shut downNOVA-II1983-2004Mexico City Instituto Nacional de Investigaciones Nucleares0.23 m/0.06 m1 T0.01 MAStudy plasma-wall interactions
JT-60 (Japan Torus-60)[8]Recycled →JT-60SA1985-2010Naka Japan Atomic Energy Research Institute3.4 m/1.0 m4 T3 MAHigh-beta steady-state operation, highest fusion triple product
DIII-D[9]Operational1986[10]1986-San Diego General Atomics1.67 m/0.67 m2.2 T3 MATokamak Optimization
STOR-M (Saskatchewan Torus-Modified)[11]Operational1987-Saskatoon Plasma Physics Laboratory (Saskatchewan)0.46 m/0.125 m1 T0.06 MAStudy plasma heating and anomalous transport
T-15Recycled →T-15MD1983-19881988-1995Moscow Kurchatov Institute2.43 m/0.7 m3.6 T1 MAFirst superconducting tokamak.
Tore Supra[12]Recycled →WEST1988-2011Cadarache Département de Recherches sur la Fusion Contrôlée2.25 m/0.7 m4.5 T2 MALarge superconducting tokamak with active cooling
ADITYA (tokamak)Operational1989-Gandhinagar Institute for Plasma Research0.75 m/0.25 m1.2 T0.25 MA
COMPASS (COMPact ASSembly)[13][14]Operational1980-1989-Prague Institute of Plasma Physics AS CR0.56 m/0.23 m2.1 T0.32 MA
FTU (Frascati Tokamak Upgrade)Operational1990-Frascati ENEA0.935 m/0.35 m8 T1.6 MA
START (Small Tight Aspect Ratio Tokamak)[15]Shut down1990-1998Culham Culham Centre for Fusion Energy0.3 m/?0.5 T0.31 MAFirst full-sized Spherical Tokamak
ASDEX Upgrade (Axially Symmetric Divertor Experiment)Operational1991-Garching Max-Planck-Institut für Plasmaphysik1.65 m/0.5 m2.6 T1.4 MA
Alcator C-Mod (Alto Campo Toro)[16]Operational (Funded by Fusion Startups)1986-1991-2016Cambridge Massachusetts Institute of Technology0.68 m/0.22 m8 T2 MArecord plasma pressure 2.05 bar
ISTTOK (Instituto Superior Técnico TOKamak)[17]Operational1992-Lisbon Instituto de Plasmas e Fusão Nuclear0.46 m/0.085 m2.8 T0.01 MA
TCV (Tokamak à Configuration Variable)[18]Operational1992-Lausanne École Polytechnique Fédérale de Lausanne0.88 m/0.25 m1.43 T1.2 MAConfinement studies
HBT-EP (High Beta Tokamak-Extended Pulse)Operational1993-New York City Columbia University Plasma Physics Laboratory0.92 m/0.15 m0.35 T0.03 MAHigh-Beta Tokamak
Pegasus Toroidal Experiment[19]Operational?1996-Madison University of Wisconsin–Madison0.45 m/0.4 m0.18 T0.3 MAExtremely low aspect ratio
NSTX (National Spherical Torus Experiment)[20]Operational1999-Plainsboro Township Princeton Plasma Physics Laboratory0.85 m/0.68 m0.3 T2 MAStudy the spherical tokamak concept
ET (Electric Tokamak)Recycled →ETPD19981999-2006Los Angeles UCLA5 m/1 m0.25 T0.045 MALargest tokamak of its time
CDX-U (Current Drive Experiment-Upgrade)Recycled →LTX2000-2005Princeton Princeton Plasma Physics Laboratory0.3 m/? m0.23 T0.03 MAStudy Lithium in plasma walls
MAST (Mega-Ampere Spherical Tokamak)[21]Recycled →MAST-Upgrade1997-19992000-2013Culham Culham Centre for Fusion Energy0.85 m/0.65 m0.55 T1.35 MAInvestigate spherical tokamak for fusion
HL-2ARecycled →HL-2M2000-20022002-2018Chengdu Southwestern Institute of Physics1.65 m/0.4 m2.7 T0.43 MAH-mode physics, ELM mitigation
SST-1 (Steady State Superconducting Tokamak)[22]Operational2001-2005-Gandhinagar Institute for Plasma Research1.1 m/0.2 m3 T0.22 MAProduce a 1000s elongated double null divertor plasma
EAST (Experimental Advanced Superconducting Tokamak)[23]Operational2000-20052006-Hefei Hefei Institutes of Physical Science1.85 m/0.43 m3.5 T0.5 MAH-Mode plasma for over 100 s at 50 MK
J-TEXT (Joint TEXT)OperationalTEXT (Texas EXperimental Tokamak)2007-Wuhan Huazhong University of Science and Technology1.05 m/0.26 m2.0 T0.2 MADevelop plasma control
KSTAR (Korea Superconducting Tokamak Advanced Research)[24]Operational1998-20072008-Daejeon National Fusion Research Institute1.8 m/0.5 m3.5 T2 MATokamak with fully superconducting magnets
LTX (Lithium Tokamak Experiment)Operational2005-20082008-Princeton Princeton Plasma Physics Laboratory0.4 m/? m0.4 T0.4 MAStudy Lithium in plasma walls
QUEST (Q-shu University Experiment with Steady-State Spherical Tokamak)[25]Operational2008-Kasuga Kyushu University0.68 m/0.4 m0.25 T0.02 MAStudy steady state operation of a Spherical Tokamak
Kazakhstan Tokamak for Material testing (KTM)Operational2000-20102010-Kurchatov National Nuclear Center of the Republic of Kazakhstan0.86 m/0.43 m1 T0.75 MATesting of wall and divertor
ST25-HTS[26]Operational2012-20152015-Culham Tokamak Energy Ltd0.25 m/0.125 m0.1 T0.02 MASteady state plasma
WEST (Tungsten Environment in Steady-state Tokamak)Operational2013-20162016-Cadarache Département de Recherches sur la Fusion Contrôlée2.5 m/0.5 m3.7 T1 MASuperconducting tokamak with active cooling
ST40[27]Operational2017-20182018-Didcot Tokamak Energy Ltd0.4 m/0.3 m3 T2 MAFirst high field spherical tokamak
MAST-U (Mega-Ampere Spherical Tokamak Upgrade)[28]Operational2013-20192019-Culham Culham Centre for Fusion Energy0.85 m/0.65 m0.92 T2 MATest new exhaust concepts for a spherical tokamak
HL-2M[29]Operational2018-20192020-Leshan Southwestern Institute of Physics1.78 m/0.65 m2.2 T1.2 MAElongated plasma with 200M °C
JT-60SA (Japan Torus-60 super, advanced)[30]Under construction2013-2020?2020?Naka Japan Atomic Energy Research Institute2.96 m/1.18 m2.25 T5.5 MAOptimise plasma configurations for ITER and DEMO with full non-inductive steady-state operation
ITER[31]Under construction2013-2025?Cadarache ITER Council6.2 m/2.0 m5.3 T15 MA ?Demonstrate feasibility of fusion on a power-plant scale with 500 MW fusion power
DTT (Divertor Tokamak Test facility)[32][33]Planned2022-2025?2025?Frascati ENEA2.14 m/0.70 m6 T ?5.5 MA ?Superconducting tokamak to study power exhaust
SPARC (Soonest/Smallest Private-Funded Affordable, Robust, Compact reactor)[34]Planned?2025?MIT Plasma Science and Fusion Center1.65 m/0.5 m12 T7.5 MACompact, high-field, fusion reactor with ReBCO coils and 100 MW planned fusion power
IGNITOR[35]Planned[36]?>2024Troitzk ENEA1.32 m/0.47 m13 T11 MA ?Compact fustion reactor with self-sustained plasma and 100 MW of planned fusion power
CFETR (China Fusion Engineering Test Reactor)[37]Planned2020?2030?Institute of Plasma Physics, Chinese Academy of Sciences5.7 m ?5 T ?10 MA ?Bridge gaps between ITER and DEMO, planned fusion power 1000 MW
STEP (Spherical Tokamak for Energy Production)Planned?2040?Culham Culham Centre for Fusion Energy3 m / 2 m ???Spherical tokamak with hundreds of MW planned electrical output
K-DEMO (Korean fusion demonstration tokamak reactor)[38]Planned2037?National Fusion Research Institute6.8 m/2.1 m7 T12 MA ?Prototype for the development of commercial fusion reactors with around 2200 MW of fusion power
DEMO (DEMOnstration Power Station)Planned2031?2044??9 m/3 m ?6 T ?20 MA ?Prototype for a commercial fusion reactor

Stellarator
Device NameStatusConstructionOperationTypeLocationOrganisationMajor/Minor RadiusB-fieldPurposeImage
Model AShut down1952-19531953-?Figure-8Princeton Princeton Plasma Physics Laboratory0.3 m/0.02 m0.1 TFirst stellarator
Model BShut down1953-19541954-1959Figure-8Princeton Princeton Plasma Physics Laboratory0.3 m/0.02 m5 TDevelopment of plasma diagnostics
Model B-1Shut down?-1959Figure-8Princeton Princeton Plasma Physics Laboratory0.25 m/0.02 m5 TYielded 1 MK plasma temperatures
Model B-2Shut down1957Figure-8Princeton Princeton Plasma Physics Laboratory0.3 m/0.02 m5 TElectron temperatures up to 10 MK
Model B-3Shut down19571958-Figure-8Princeton Princeton Plasma Physics Laboratory0.4 m/0.02 m4 TLast figure-8 device, confinement studies of ohmically heated plasma
Model B-64Shut down19551955SquarePrinceton Princeton Plasma Physics Laboratory? m/0.05 m1.8 T
Model B-65Shut down19571957RacetrackPrinceton Princeton Plasma Physics Laboratory
Model B-66Shut down19581958-?RacetrackPrinceton Princeton Plasma Physics Laboratory
Wendelstein 1-AShut down1960RacetrackGarching Max-Planck-Institut für Plasmaphysik0.35 m/0.02 m2 Tℓ=3
Wendelstein 1-BShut down1960RacetrackGarching Max-Planck-Institut für Plasmaphysik0.35 m/0.02 m2 Tℓ=2
Model CRecycled →ST1957-19621962-1969RacetrackPrinceton Princeton Plasma Physics Laboratory1.9 m/0.07 m3.5 TFound large plasma losses by Bohm diffusion
L-1Shut down19631963-1971Lebedev Lebedev Physical Institute0.6 m/0.05 m1 T
SIRIUSShut down1964-?Kharkov
TOR-1Shut down19671967-1973Lebedev Lebedev Physical Institute0.6 m/0.05 m1 T
TOR-2Shut down?1967-1973Lebedev Lebedev Physical Institute0.63 m/0.036 m2.5 T
Wendelstein 2-AShut down1965-19681968-1974HeliotronGarching Max-Planck-Institut für Plasmaphysik0.5 m/0.05 m0.6 TGood plasma confinement “Munich mystery”
Wendelstein 2-BShut down?-19701971-?HeliotronGarching Max-Planck-Institut für Plasmaphysik0.5 m/0.055 m1.25 TDemonstrated similar performance than tokamaks
L-2Shut down?1975-?Lebedev Lebedev Physical Institute1 m/0.11 m2.0 T
WEGARecycled →HIDRA1972-19751975-2013Classical stellaratorGreifswald Max-Planck-Institut für Plasmaphysik0.72 m/0.15 m1.4 TTest lower hybrid heating
Wendelstein 7-AShut down?1975-1985Classical stellaratorGarching Max-Planck-Institut für Plasmaphysik2 m/0.1 m3.5 TFirst "pure" stellarator without plasma current
Heliotron-EShut down?1980-?Heliotron2.2 m/0.2 m1.9 T
Heliotron-DRShut down?1981-?Heliotron0.9 m/0.07 m0.6 T
Uragan-3 (M)[39]Operational?1982-?[40]TorsatronKharkiv National Science Center, Kharkiv Institute of Physics and Technology (NSC KIPT)1.0 m/0.12 m1.3 T?
Auburn Torsatron (AT)Shut down?1984-1990TorsatronAuburn Auburn University0.58 m/0.14 m0.2 T
Wendelstein 7-ASShut down1982-19881988-2002Modular, advanced stellaratorGarching Max-Planck-Institut für Plasmaphysik2 m/0.13 m2.6 TFirst H-mode in a stellarator in 1992
Advanced Toroidal Facility (ATF)Shut down1984-1988[41]1988-?TorsatronOak Ridge Oak Ridge National Laboratory2.1 m/0.27 m2.0 THigh-beta operation
Compact Helical System (CHS)Shut down?1989-?HeliotronToki National Institute for Fusion Science1 m/0.2 m1.5 T
Compact Auburn Torsatron (CAT)Shut down?-19901990-2000TorsatronAuburn Auburn University0.53 m/0.11 m0.1 TStudy magnetic flux surfaces
H-1NF[42]Operational1992-HeliacCanberra Research School of Physical Sciences and Engineering, Australian National University1.0 m/0.19 m0.5 T
TJ-K[43]OperationalTJ-IU1994-TorsatronKiel, Stuttgart University of Stuttgart0.60 m/0.10 m0.5 TTeaching
TJ-II[44]Operational1991-1997-flexible HeliacMadrid National Fusion Laboratory, Centro de Investigaciones Energéticas, Medioambientales y Tecnológicas1.5 m/0.28 m1.2 TStudy plasma in flexible configuration
LHD (Large Helical Device)[45]Operational1990-19981998-HeliotronToki National Institute for Fusion Science3.5 m/0.6 m3 TDetermine feasibility of a stellarator fusion reactor
HSX (Helically Symmetric Experiment)Operational1999-Modular, quasi-helically symmetricMadison University of Wisconsin–Madison1.2 m/0.15 m1 Tinvestigate plasma transport
Heliotron J (Heliotron J)[46]Operational2000-HeliotronKyoto Institute of Advanced Energy1.2 m/0.1 m1.5 TStudy helical-axis heliotron configuration
Columbia Non-neutral Torus (CNT)Operational?2004-Circular interlocked coilsNew York City Columbia University0.3 m/0.1 m0.2 TStudy of non-neutral plasmas
Uragan-2(M)[47]Operational1988-20062006-[48]Heliotron, TorsatronKharkiv National Science Center, Kharkiv Institute of Physics and Technology (NSC KIPT)1.7 m/0.24 m2.4 T?
Quasi-poloidal stellarator (QPS)[49][50]Cancelled2001-2007-ModularOak Ridge Oak Ridge National Laboratory0.9 m/0.33 m1.0 TStellarator research
NCSX (National Compact Stellarator Experiment)Cancelled2004-2008-HeliasPrinceton Princeton Plasma Physics Laboratory1.4 m/0.32 m1.7 THigh-β stability
Compact Toroidal Hybrid (CTH)Operational?2007?-TorsatronAuburn Auburn University0.75 m/0.2 m0.7 THybrid stellarator/tokamak
HIDRA (Hybrid Illinois Device for Research and Applications)[51]Operational2013-2014 (WEGA)2014-?Urbana, IL University of Illinois0.72 m/0.19 m0.5 TStellarator and Tokamak in one device
UST_2[52]Operational20132014-modular three period quasi-isodynamicMadrid Charles III University of Madrid0.29 m/0.04 m0.089 T3D printed stellarator
Wendelstein 7-X[53]Operational1996-20152015-HeliasGreifswald Max-Planck-Institut für Plasmaphysik5.5 m/0.53 m3 TSteady-state plasma in fully optimized stellarator
SCR-1 (Stellarator of Costa Rica)Operational2011-20152016-ModularCartago Instituto Tecnológico de Costa Rica0.14 m/0.042 m0.044 T

Reversed field pinch (RFP)
  • ETA-BETA II in Padua, Italy (1979-1989)
  • RFX (Reversed-Field eXperiment), Consorzio RFX, Padova, Italy[54]
  • MST (Madison Symmetric Torus), University of Wisconsin–Madison, United States[55]
  • T2R, Royal Institute of Technology, Stockholm, Sweden
  • TPE-RX, AIST, Tsukuba, Japan
  • KTX (Keda Torus eXperiment) in China (since 2015)[56]

Magnetic mirror

Spheromak

Field-Reversed Configuration (FRC)

Open field lines

Plasma pinch
  • Trisops - 2 facing theta-pinch guns

Levitated Dipole

Inertial confinement
Main article: Inertial confinement fusion

Laser-driven

Current or under construction experimental facilities
Solid state lasers
Gas lasers
  • NIKE laser at the Naval Research Laboratories, Krypton Fluoride gas laser
  • PALS, formerly the "Asterix IV", at the Academy of Sciences of the Czech Republic,[61] 1 kJ max. output iodine laser at 1.315 micrometre fundamental wavelength

Dismantled experimental facilities
Solid-state lasers
Gas lasers
  • "Single Beam System" or simply "67" after the building number it was housed in, a 1 kJ carbon dioxide laser at Los Alamos National Laboratory
  • Gemini laser, 2 beams, 2.5 kJ carbon dioxide laser at LANL
  • Helios laser, 8 beam, ~10 kJ carbon dioxide laser at LANL Media at Wikimedia Commons
  • Antares laser at LANL. (40 kJ CO2 laser, largest ever built, production of hot electrons in target plasma due to long wavelength of laser resulted in poor laser/plasma energy coupling)
  • Aurora laser 96 beam 1.3 kJ total krypton fluoride (KrF) laser at LANL
  • Sprite laser few joules/pulse laser at the Central Laser Facility, Rutherford Appleton Laboratory

Z-Pinch
Main article: Z-Pinch

Inertial electrostatic confinement
Main article: Inertial electrostatic confinement

Magnetized target fusion
Main article: Magnetized target fusion
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