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Title: Non-inductive current drive and transport in high beta(N) plasmas in JET

Journal Article · · Nuclear Fusion
 [1];  [2];  [1];  [3];  [4];  [1];  [5];  [2];  [6];  [1];  [5];  [3];  [3];  [7];  [7]
  1. UKAEA Fusion, Culham UK
  2. EURATOM / UKAEA, UK
  3. Princeton Plasma Physics Laboratory (PPPL)
  4. ENEA, Frascati
  5. General Atomics, San Diego
  6. CEA Cadarache, St. Paul lex Durance, France
  7. ORNL
+ Show Author Affiliations

A route to stationary MHD stable operation at high beta(N) has been explored at the Joint European Torus (JET) by optimizing the current ramp-up, heating start time and the waveform of neutral beam injection (NBI) power. In these scenarios the current ramp-up has been accompanied by plasma pre-heat (or the NBI has been started before the current flat-top) and NBI power up to 22 MW has been applied during the current flat-top. In the discharges considered transient total beta(N) approximate to 3.3 and stationary (during high power phase) beta(N) approximate to 3 have been achieved by applying the feedback control of beta(N) with the NBI power in configurations with monotonic or flat core safety factor profile and without an internal transport barrier (ITB). The transport and current drive in this scenario is analysed here by using the TRANSP and ASTRA codes. The interpretative analysis performed with TRANSP shows that 50-70% of current is driven non-inductively; half of this current is due to the bootstrap current which has a broad profile since an ITB was deliberately avoided. The GLF23 transport model predicts the temperature profiles within a +/- 22% discrepancy with the measurements over the explored parameter space. Predictive simulations with this model show that the E x B rotational shear plays an important role for thermal ion transport in this scenario, producing up to a 40% increase of the ion temperature. By applying transport and current drive models validated in self-consistent simulations of given reference scenarios in a wider parameter space, the requirements for fully non-inductive stationary operation at JET are estimated. It is shown that the strong stiffness of the temperature profiles predicted by the GLF23 model restricts the bootstrap current at larger heating power. In this situation full non-inductive operation without an ITB can be rather expensive strongly relying on the external non-inductive current drive sources.

Research Organization:
Oak Ridge National Lab. (ORNL), Oak Ridge, TN (United States)
Sponsoring Organization:
USDOE Office of Science (SC)
DOE Contract Number:
DE-AC05-00OR22725
OSTI ID:
1015755
Journal Information:
Nuclear Fusion, Vol. 49, Issue 5; ISSN 0029--5515
Country of Publication:
United States
Language:
English

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Related Subjects

99 GENERAL AND MISCELLANEOUS//MATHEMATICS, COMPUTING, AND INFORMATION SCIENCE
BEAM INJECTION
BOOTSTRAP CURRENT
FEEDBACK
FLEXIBILITY
HEATING
ION TEMPERATURE
NON-INDUCTIVE CURRENT DRIVE
PLASMA
SAFETY
SHEAR
TRANSIENTS
TRANSPORT
WAVE FORMS