Heliotron J

Heliotron J
Technical specifications
Device type	Stellarator
Location	Japan
Affiliation	Kyoto University
Major radius	1.2 m (3 ft 11 in)
Minor radius	0.1–0.2 m (3.9 in – 7.9 in)
Magnetic field	1.5 T (15,000 G)
History
Year(s) of operation	2000–present
Links
Website	Heliotron J at the Institute of Advanced Energy, Kyoto University

Heliotron J is a fusion research device in Japan, specifically a helical-axis heliotron designed to study plasma confinement in this type of device.^[1]^[2]^[3] It is located at the Institute of Advanced Energy of Kyoto University.^[4]

References

^ "The Laboratory for Complex Energy Processes". Institute of Advanced Energy, Kyoto University. Archived from the original on 2016-04-17.
^ Okada, H.; Kobayashi, S.; Nagasaki, K.; Mizuuchi, T.; Yamamoto, S.; Motojima, G.; Watanabe, S.; Mukai, K.; Mihara, S.; Kowada, Y.; Hosaka, K.; Matsuyama, A.; Nakamura, Y.; Hanatani, K.; Nishino, N.; Nakashima, Y.; Nagaoka, K.; Mutoh, T.; Suzuki, Y.; Yokoyama, M.; Konoshima, S.; Kondo, K.; Sano, F. "Configuration Control Experiment in Heliotron J" (PDF). Retrieved 25 September 2018.
^ Obiki, T.; Mizuuchi, T.; Nagasaki, K.; Okada, H.; Besshou, S.; Sano, F.; Kondo, K.; Liu, Y.; Nakamura, Y.; Hanatani, K.; Nakasuga, M.; Wakatani, M.; Hamada, T.; Manabe, Y.; Shidara, H.; Yamagishi, O.; Aizawa, K.; Ang, W. L.; Ikeda, Y. I.; Kawazome, Y.; Kobayashi, T.; Maeno, S.; Takamiya, T.; Takeda, M.; Tomiyama, K.; Ijiri, Y.; Senju, T.; Yaguchi, K.; Sakamoto, K.; Toshi, K.; Shibano, M. (2000), First Plasmas in Heliotron J, Sorrento, Italy: IAEA, retrieved 2018-09-25
^ Obiki, T; Sano, F; Wakatani, M; Kondo, K; Mizuuchi, T; Hanatani, K; Nakamura, Y; Nagasaki, K; Okada, H; Nakasuga, M; Besshou, S (2000). "Goals and status of Heliotron J". Plasma Physics and Controlled Fusion. 42 (11): 1151–1164. Bibcode:2000PPCF...42.1151O. doi:10.1088/0741-3335/42/11/302. ISSN 0741-3335. S2CID 250734022.

Fusion power, processes and devices

Core topics

Nuclear fusion
- Timeline
- List of experiments
Nuclear power
Nuclear reactor
Atomic nucleus
Fusion energy gain factor
Lawson criterion
Magnetohydrodynamics
Neutron
Plasma

Processes,
methods

Confinement
type

Gravitational	Alpha process Triple-alpha process CNO cycle Fusor Helium flash Nova remnants Proton–proton chain Carbon-burning Lithium burning Neon-burning Oxygen-burning Silicon-burning R-process S-process
Magnetic	Dense plasma focus Field-reversed configuration Levitated dipole Magnetic mirror Bumpy torus Reversed field pinch Spheromak Stellarator Theta pinch Tokamak Spherical Toroidal solenoid Z-pinch
Inertial	Bubble (acoustic) Laser-driven Ion-driven Magnetized liner inertial fusion
Electrostatic	Fusor Polywell

Other forms

Devices,
experiments

Magnetic
confinement

Tokamak

International	ITER DEMO PROTO
Americas	STOR-M Alcator C-Mod ARC SPARC DIII-D Electric Tokamak LTX NSTX PLT TFTR Pegasus ETE TCABR Novillo [es]
Asia, Oceania	CFETR EAST HT-7 HL-2A HL-2M SUNIST ADITYA SST-1 JT-60 QUEST [ja] GLAST KSTAR TT-1
Europe	JET COMPASS GOLEM [cs] TFR WEST ASDEX Upgrade TEXTOR DTT FTU IGNITOR ISTTOK T-15 TCV MAST-U START STEP

Stellarator

Americas	CNT CTH HIDRA HSX Model C NCSX SCR-1
Asia, Oceania	H-1NF Heliotron J LHD
Europe	WEGA Wendelstein 7-AS Wendelstein 7-X TJ-II Uragan-2M Uragan-3M [uk]

RFP

Magnetized target

Other

Inertial
confinement

Laser

Americas	Argus Cyclops Janus LIFE Long path NIF Nike Nova OMEGA Shiva
Asia	GEKKO XII
Europe	HiPER Asterix IV (PALS) LMJ LULI2000 ISKRA Vulcan