Internal Transport Barrier: Difference between revisions

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Factors contributing to the formation of ITBs include:
Factors contributing to the formation of ITBs include:
<ref>[http://dx.doi.org/10.1088/0029-5515/44/4/R01 J.W. Connor et al, ''A review of internal transport barrier physics for steady-state operation of tokamaks'', Nucl. Fusion '''44''' (2004) R1-R49]</ref>
<ref>[http://dx.doi.org/10.1088/0029-5515/44/4/R01 J.W. Connor et al, ''A review of internal transport barrier physics for steady-state operation of tokamaks'', Nucl. Fusion '''44''' (2004) R1-R49]</ref>
* Power deposited inside the magnetic surface, and/or pressure gradients
* Power deposited inside the [[Flux surface|magnetic surface]], and/or pressure gradients
* [[Magnetic shear]] and the shape of the profile of the rotational transform
* [[Magnetic shear]] and the shape of the rotational transform profile
* MHD activity
* MHD activity
* Momentum torques (poloidal or toroidal)
* Momentum torques (poloidal or toroidal)

Revision as of 15:44, 27 August 2009

No generally accepted definition for Internal Transport Barriers (ITBs) exists. Vaguely speaking, the term refers to a radially localized reduction of transport for ions or electrons.

ITBs can be actively produced by modifying the current profile using external means. [1] They are used to improve plasma confinement and stability properties, and to drive additional bootstrap current. Therefore, they are included in some alternative operational scenarios for ITER.

Physical mechanism

The mechanism for the formation of Internal Transport Barriers in magnetically confined plasmas is complex and not fully understood. Probably, it is related to the mechanism for the formation of the H-mode barrier, involving turbulence suppression by sheared flows, and possibly associated with rational magnetic surfaces.

Factors contributing to the formation of ITBs include: [2]

  • Power deposited inside the magnetic surface, and/or pressure gradients
  • Magnetic shear and the shape of the rotational transform profile
  • MHD activity
  • Momentum torques (poloidal or toroidal)

References

  1. R.C. Wolf, Internal transport barriers in tokamak plasmas, Plasma Phys. Control. Fusion 45 (2003) R1-R91
  2. J.W. Connor et al, A review of internal transport barrier physics for steady-state operation of tokamaks, Nucl. Fusion 44 (2004) R1-R49
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