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**Harvard**

Weiland, J. och Mantica, P. (2011) *Effects of flow shear on the correlation length of drift wave turbulence*.

** BibTeX **

@conference{

Weiland2011,

author={Weiland, Jan and Mantica, P.},

title={Effects of flow shear on the correlation length of drift wave turbulence},

booktitle={38th EPS Conference on Plasma Physics 2011, EPS 2011. Strasbourg, 27 June - 1 July 2011},

isbn={978-161839593-1},

abstract={Experiments on JET1 have shown that stiffness of ion energy transport above a threshold gradient is strongly reduced in the plasma core due to flow shear. Initially transport models had difficulties to reproduce this feature. Later TGLF2 has reproduced the trend, particularly in the region of low normalized heat flux, i.e. near threshold . Also Gyro4 simulations have been made but these are still uncertain. The experimental observations also indicated in more detail that it is the combination of high flow shear and small magnetic shear that leads to stiffness reduction. This naturally limits the region of stiffness mitigation to the interior of tokamaks3. Since flow shear stabilizes drift wave transport by damping out primarily long wavelength perturbations, it is obvious that it influences the correlation length. Thus it was natural to generalize our previous work on making the correlation length for drift waves parameter dependent to include also the effect of flow shear. This has now been implemented and is found to reproduce the experimental feature that stiffness is reduced for a combination of large flow shear and small magnetic shear. The reason is that for large magnetic shear the radial correlation length is determined primarily by magnetic shear, whilst for low magnetic shear it is determined by flowshear. The first results of this modified correlation length model show good quantitative agreement with experiment.
},

year={2011},

keywords={Correlation lengths, Drift waves, Experimental observation, Flow shear, High flow, Ion energies, Long wavelength, Magnetic shear, Plasma core, Quantitative agreement, Radial correlation lengths, Stiffness reduction, Transport models},

}

** RefWorks **

RT Conference Proceedings

SR Print

ID 166120

A1 Weiland, Jan

A1 Mantica, P.

T1 Effects of flow shear on the correlation length of drift wave turbulence

YR 2011

T2 38th EPS Conference on Plasma Physics 2011, EPS 2011. Strasbourg, 27 June - 1 July 2011

SN 978-161839593-1

AB Experiments on JET1 have shown that stiffness of ion energy transport above a threshold gradient is strongly reduced in the plasma core due to flow shear. Initially transport models had difficulties to reproduce this feature. Later TGLF2 has reproduced the trend, particularly in the region of low normalized heat flux, i.e. near threshold . Also Gyro4 simulations have been made but these are still uncertain. The experimental observations also indicated in more detail that it is the combination of high flow shear and small magnetic shear that leads to stiffness reduction. This naturally limits the region of stiffness mitigation to the interior of tokamaks3. Since flow shear stabilizes drift wave transport by damping out primarily long wavelength perturbations, it is obvious that it influences the correlation length. Thus it was natural to generalize our previous work on making the correlation length for drift waves parameter dependent to include also the effect of flow shear. This has now been implemented and is found to reproduce the experimental feature that stiffness is reduced for a combination of large flow shear and small magnetic shear. The reason is that for large magnetic shear the radial correlation length is determined primarily by magnetic shear, whilst for low magnetic shear it is determined by flowshear. The first results of this modified correlation length model show good quantitative agreement with experiment.

LA eng

OL 30