EAST

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For the cardinal direction see East, for other uses see East (disambiguation)

EAST fusion termonuclear reactor, build at the cost of 200 million ¥

The Experimental Advanced Superconducting Tokamak (EAST, internal designation HT-7U) is an experimental superconducting tokamak magnetic fusion energy reactor in Hefei, the capital city of Anhui Province, in eastern China. The experiment is being conducted by the Hefei-based Institute of Plasma Physics under the Chinese Academy of Sciences. The project was proposed in 1996 and approved in 1998. According to a 2003 schedule,^[1] buildings and site facilities were to be constructed by 2003, and tokamak assembly to take place from 2003 through 2005.

Construction was completed in March 2006 and on September 28, 2006, "first plasma" was achieved. In February 2007 the reactor sustained an electrical current of 250 KA for five seconds.^[2]

The reactor is an improvement over China's first superconducting tokamak device, dubbed HT-7, also built by the Institute of Plasma Physics in partnership with Russia in the early 1990s.

According to official reports, the project's budget is a relatively small CNY ¥300 million (approx. USD $37 million), some 1/15 to 1/20 the cost of a comparable reactor built in other countries.^[3]

1 Physics objectives
2 Tokamak parameters
3 References
4 External links

[edit] Physics objectives

China is a member of the ITER consortium, and EAST will be a testbed for technologies proposed for the ITER project.

EAST will test:

Superconducting NbTi poloidal field magnets, making it the first tokamak with superconducting toroidal and poloidal magnets
Non-inductive current drive
Pulses of up to 1000 seconds with 0.5 MA plasma current
Schemes for controlling plasma instabilities through real-time diagnostics
Materials for divertors and plasma facing components
Operation with β_N = 2 and H₈₉ > 2

[edit] Tokamak parameters

Toroidal field, B_θ	3.5 T
Plasma current, I_P	0.5 MA
Major radius, R₀	1.7 m
Minor radius, a	0.4 m
Aspect ratio, R/a	4.25
Elongation, κ	1.6 - 2
Triangularity, δ	0.6 - 0.8
Ion cyclotron resonance heating (ICRH)	3 MW
Lower hybrid current drive (LHCD)	4 MW
Electron cyclotron resonance heating (ECRH)	0.5 MW
Neutral beam injection (NBI)	None currently
Pulse length	1-1000 s
Configuration	Double-null divertor Pump limiter Single null divertor

Fusion power v • d • e
Atomic nucleus \| Nuclear fusion \| Nuclear power \| Nuclear reactor \| Timeline of nuclear fusion Plasma physics \| Magnetohydrodynamics \| Neutron flux \| Fusion energy gain factor \| Lawson criterion
Methods of fusing nuclei
Magnetic confinement: - Tokamak - Spheromak - Stellarator - Reversed field pinch - Field-Reversed Configuration - Levitated Dipole Inertial confinement: - Laser driven - Z-pinch - Bubble fusion (acoustic confinement) - Fusor (electrostatic confinement) Other forms of fusion: - Muon-catalyzed fusion - Pyroelectric fusion - Migma
List of fusion experiments
Magnetic confinement devices ITER (International) \| JET (European) \| JT-60 (Japan) \| Large Helical Device (Japan) \| KSTAR (Korea) \| EAST (China) \| T-15 (Russia) \| DIII-D (USA) \| Tore Supra (France) \| ASDEX Upgrade (Germany) \| TFTR (USA) \| NSTX (USA) \| NCSX (USA) \| UCLA ET (USA) \| Alcator C-Mod (USA) \| LDX (USA) \| H-1NF (Australia) \| MAST (UK) \| START (UK) \| Wendelstein 7-X (Germany) \| TCV (Switzerland) \| DEMO (Commercial) Inertial confinement devices Laser driven: - NIF (USA) \| OMEGA laser (USA) \| Nova laser (USA) \| Novette laser (USA) \| Nike laser (USA) \| Shiva laser (USA) \| Argus laser (USA) \| Cyclops laser (USA) \| Janus laser (USA) \| Long path laser (USA) \| 4 pi laser (USA) \| LMJ (France) \| Luli2000 (France) \| GEKKO XII (Japan) \| ISKRA lasers (Russia) \| Vulcan laser (UK) \| Asterix IV laser (Czech Republic) \| HiPER laser (European) Non-laser driven: - Z machine (USA) \| PACER (USA) See also: International Fusion Materials Irradiation Facility