Physics – Space Physics
Scientific paper
2009-03-02
Ann. Geophys., 28, 1-5, 2010 (published with authors in alphabetical order)
Physics
Space Physics
pdf-LaTex manuscript, 9 pages, 2 figure, theoretical: Weibel instability in thin current sheets
Scientific paper
In thin ($\Delta<$ few $\lambda_i$) collisionless current sheets in a space plasma like the magnetospheric tail or magnetopause current layer, magnetic fields can grow {from thermal fluctuation level by the action of the non-magnetic Weibel instability \citep{weibel1959}.}The instability is driven by the counter-streaming electron inflow from the `ion diffusion' (ion inertial Hall) region into the inner current (electron inertial) region from where the ambient magnetic fields are excluded when released by the inflowing electrons which become non-magnetic on scales smaller than the electron gyroradius and $<$ few $\lambda_e$. It is shown that under magnetospheric tail conditions it takes $\sim$ 20-40 e-folding times ($\sim$ 10-20 s) for the Weibel field to reach observable amplitudes $|{\bf b}_{\rm W}|\sim 1$ nT. In counter-streaming inflows these fields are predominantly of guide field type. This is of interest in magnetic guide field reconnection. Guide fields are known to possibly providing the conditions required for the onset of bursty reconnection \citep {drake2006,pritchett2005a,pritchett2006a,cassak2007}. In non-symmetric inflows the Weibel field might itself evolve a component normal to the current sheet which could also contribute to reconnection onset.
Baumjohann Wolfgang
Nakamura Riou
Treumann Rudolf A.
No associations
LandOfFree
Magnetic guide field generation in thin collisionless current sheets does not yet have a rating. At this time, there are no reviews or comments for this scientific paper.
If you have personal experience with Magnetic guide field generation in thin collisionless current sheets, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Magnetic guide field generation in thin collisionless current sheets will most certainly appreciate the feedback.
Profile ID: LFWR-SCP-O-78418