Physics of Plasmas
Feedback | Help | Exit
Physics of Plasmas
   
 
 
 
Previous Article
Kinetic theory of radial angular momentum flux of collisional plasmas in an axisymmetric magnetic field
A recent calculation [P. J. Catto and A. N. Simakov, Phys. Plasmas 12, 012501 (2005)] of the radial angular momentum flux for collisional plasmas with small toroidal flows using fluid equations is at ...
Next Article
High-beta plasma effects in a low-pressure helicon plasma
In this work, high-beta plasma effects are investigated in a low-pressure helicon plasma source attached to a large volume diffusion chamber. When operating above an input power of 900  W an...

Hypersonic drift-tearing magnetic islands in tokamak plasmas

Phys. Plasmas 14, 122502 (2007); doi:10.1063/1.2811928

Published 6 December 2007

You are not logged in to this journal. Log in

R. Fitzpatrick and F. L. Waelbroeck
Institute for Fusion Studies, Department of Physics, University of Texas at Austin, Austin, Texas 78712, USA
A two-fluid theory of long wavelength, hypersonic, drift-tearing magnetic islands in low-collisionality, low-beta plasmas possessing relatively weak magnetic shear is developed. The model assumes both slab geometry and cold ions, and neglects electron temperature and equilibrium current gradient effects. The problem is solved in three asymptotically matched regions. The “inner region” contains the island. However, the island emits electrostatic drift-acoustic waves that propagate into the surrounding “intermediate region,” where they are absorbed by the plasma. Since the waves carry momentum, the inner region exerts a net force on the intermediate region, and vice versa, giving rise to strong velocity shear in the region immediately surrounding the island. The intermediate region is matched to the surrounding “outer region,” in which ideal magnetohydrodynamic holds. Isolated hypersonic islands propagate with a velocity that lies between those of the unperturbed local ion and electron fluids, but is much closer to the latter. The ion polarization current is stabilizing, and increases with increasing island width. Finally, the hypersonic branch of isolated island solutions ceases to exist above a certain critical island width. Hypersonic islands whose widths exceed the critical width are hypothesized to bifurcate to the so-called “sonic” solution branch. ©2007 American Institute of Physics
History: Received 7 September 2007; accepted 22 October 2007; published 6 December 2007
Permalink: http://link.aip.org/link/?PHPAEN/14/122502/1
BUY THIS ARTICLE   (US$28)
Download PDF (197 kB) View Cart

KEYWORDS and PACS

Keywords
PACS
  • 52.35.Py
    Plasma macroinstabilities (hydromagnetic) e.g., kink, fire-hose, mirror, ballooning, tearing, trapped-particle, flute, Rayleigh-Taylor instabilities, etc
  • 52.30.Cv
    Plasma magnetohydrodynamics including electron magnetohydrodynamics
  • 52.55.Fa
    Tokamaks
  • 52.35.Kt
    Plasma drift waves
  • 52.35.Fp
    Plasma electrostatic waves and oscillations e.g., ion-acoustic waves
  • 52.35.Dm
    Plasma sound waves
  • YEAR: 2007

RELATED DATABASES


To view database links for this article,
you need to log in.
To view database links for this article,
you need to log in.

PUBLICATION DATA

ISSN:
1070-664X (print)   1089-7674 (online)
Publisher:
AIP is a member of CrossRef AIP

REFERENCES (26)
View in Separate Window/Tab
For access to fully linked references, you need to log in. For access to fully linked references, you need to Log in.
  1. H. P. Furth, J. Killeen, and M. N. Rosenbluth, Phys. Fluids 6, 459 (1963).
  2. M. N. Rosenbluth, Plasma Phys. Controlled Fusion 41, A99 (1999).
  3. P. H. Rutherford, Phys. Fluids 16, 1903 (1973).
  4. Z. Chang and J. D. Callen, Nucl. Fusion 30, 219 (1990).
  5. B. D. Scott, A. B. Hassam, and J. F. Drake, Phys. Fluids 28, 275 (1985).
  6. B. D. Scott and A. B. Hassam, Phys. Fluids 30, 90 (1987).
  7. A. I. Smolyakov, Plasma Phys. Controlled Fusion 35, 657 (1993).
  8. A. B. Mikhailovskii, Contrib. Plasma Phys. 43, 125 (2003).
  9. G. Ara, B. Basu, B. Coppi, G. Laval, M. N. Rosenbluth, and B. V. Waddell, Ann. Phys. (N.Y.) 112, 443 (1978).
  10. J. F. Drake and Y. C. Lee, Phys. Fluids 20, 134 (1977).
  11. R. D. Hazeltine and J. D. Meiss, Phys. Rep. 121, 1 (1985).
  12. R. D. Hazeltine and J. D. Meiss, Plasma Confinement (Dover, Mineola, 2003).
  13. M. Ottaviani, F. Porcelli, and D. Grasso, Phys. Rev. Lett. 93, 075001 (2004).
  14. R. Fitzpatrick, F. L. Waelbroeck, and F. Militello, Phys. Plasmas 13, 122507 (2006).
  15. R. Fitzpatrick and F. L. Waelbroeck, Phys. Plasmas 12, 122511 (2005).
  16. F. L. Waelbroeck, Plasma Phys. Controlled Fusion 49, 905 (2007).
  17. R. D. Hazeltine, M. Kotschenreuther, and P. J. Morrison, Phys. Fluids 28, 2466 (1985).
  18. J. W. Connor, F. L. Waelbroeck, and H. R. Wilson, Phys. Plasmas 8, 2835 (2001).
  19. F. L. Waelbroeck, J. W. Connor, and H. R. Wilson, Phys. Rev. Lett. 87, 215003 (2001).
  20. F. L. Waelbroeck, Phys. Rev. Lett. 95, 035002 (2005).
  21. P. H. Rutherford, in Basic Physical Processes of Toroidal Fusion Plasmas, Proc. Course and Workshop, Varenna, 1985 (Commission of the European Communities, Brussels, 1986) Vol. 2, p. 531.
  22. J. F. Drake, J. T. M. Antonsen, A. B. Hassam, and N. T. Gladd, Phys. Fluids 26, 2509 (1983).
  23. L. D. Pearlstein and H. L. Berk, Phys. Rev. Lett. 23, 220 (1969).
  24. D. Grasso, M. Ottaviani, and F. Porcelli, Nucl. Fusion 42, 1067 (2002).
  25. F. L. Waelbroeck and R. Fitzpatrick, Phys. Rev. Lett. 78, 1703 (1997).
  26. M. N. Bussac, D. Edery, R. Pellat, and J. L. Soule, Phys. Rev. Lett. 40, 1500 (1978).

CITING ARTICLES
For access to citing articles, you need to log in.
For access to citing articles, you need to Log in.


Copyright © American Institute of Physics