Entropy antidiffusion instability and formation of a thin current sheet during geomagnetic substorms

Lee, L. C.; Zhang, L.; Otto, A.; Choe, G. S.; Cai, H. J.

doi:10.1029/97ja02141

Cited by 27 publications

(22 citation statements)

References 21 publications

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“…2K). This sequence is in agreement with several previous studies and the inside-out model of substorm onset (4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)(15).…”

supporting

confidence: 81%

Comment on “Tail Reconnection Triggering Substorm Onset”

Lui

2009

Science

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Angelopoulos et al . (Research Articles, 15 August 2008, p. 931) reported that magnetic reconnection in Earth’s magnetotail triggered the onset of a magnetospheric substorm. We provide evidence that (i) near-Earth current disruption, occurring before the conventional tail reconnection signatures, triggered the onset; (ii) the observed auroral intensification and tail reconnection are not causally linked; and (iii) the onset they identified is a continuation of earlier substorm activities.

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“…2K). This sequence is in agreement with several previous studies and the inside-out model of substorm onset (4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)(15).…”

supporting

confidence: 81%

Comment on “Tail Reconnection Triggering Substorm Onset”

Lui

2009

Science

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“…In the inner tail (∣ X ∣ < 15 R E ) there are observational indications however [e.g., Borovsky et al , 1998] that entropy conservation is violated. A process called entropy anti‐diffusion has been proposed [ Lee et al , 1998] to explain thin current sheet formation in such a situation. The magnetospheric evolution in the model of Lee et al [1998] is however characterized by significant flows, a result not supported by growth phase observations.…”

Section: Introductionmentioning

confidence: 99%

“…A process called entropy anti‐diffusion has been proposed [ Lee et al , 1998] to explain thin current sheet formation in such a situation. The magnetospheric evolution in the model of Lee et al [1998] is however characterized by significant flows, a result not supported by growth phase observations.…”

Section: Introductionmentioning

confidence: 99%

Near‐Earth thin current sheets and Birkeland currents during substorm growth phase

Zaharia

Cheng

2003

Geophysical Research Letters

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[1] Two important observed substorm growth phase phenomena are modeled: the formation of a near-Earth (jXj $ 8 R E ) thin cross-tail current sheet, as well as the equatorward shift of the ionospheric Birkeland currents. Our study is performed by solving the 3D force-balance equation with realistic boundary conditions and pressure distributions. The obtained cross-tail current sheet has large current density (J f $ 10 nA/m 2 ) and a half-thickness in the north-south direction of $1 R E , while plasma b is very high (b $ 40) in the current sheet region. The Region-1 and Region-2 Birkeland currents, formed on closed field lines due to pressure gradients, move equatorward and become more intense (J kmax $ 3 mA/m 2 ) compared to quiet times. The results agree with growth phase observations. We also find that the cross-tail current sheet maps into the ionosphere in the transition region between the Region-1 and Region-2 currents.

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“…Without entropy conservation, a process called entropy anti-diffusion has been proposed ] to explain thin current sheet formation in 2D with symmetry in the Y-direction. The magnetospheric evolution in the model of Lee et al [1998] is however characterized by significant flows, a result not supported by observations during the growth phase. It should be noted that these modeling efforts were performed in 2D geometries.…”

Section: Current Sheetmentioning

confidence: 62%

Physics of Substorm Growth Phase, Onset, and Dipolarization

Cheng¹

2003

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Abstract.A new scenario of substorm growth phase, onset and dipolarization during expansion phase and the corresponding physical processes are presented. During the growth phase, as a result of enhanced plasma convection, the plasma pressure and its gradient are continued to be enhanced over the quiet-time values in the plasma sheet.Toward the late growth phase, a strong cross-tail current sheet is formed in the nearEarth plasma sheet region, where a local magnetic well is formed, the plasma beta can reach a local maximum with value larger than 50 and the cross-tail current density can be enhanced to over 10nA/m 2 as obtained from 3D quasi-static magnetospheric equilibrium solutions for the growth phase. The most unstable kinetic ballooning instabilities (KBI) are expected to be located in the tailward side of the strong cross-tail current sheet region.The field lines in the most unstable KBI region map to the transition region between the region-1 and region-2 currents in the ionosphere, which is consistent with the observed initial brightening location of the breakup arc in the intense proton precipitation region.The KBI explains the AMPTE/CCE observations that a low frequency instability with a wave period of 50 − 75 seconds is excited about 2-3 minutes prior to substorm onset and grows exponentially to a large amplitude at the onset of current disruption (or current reduction). At the current disruption onset higher frequency instabilities are excited so that the plasma and electromagnetic field fluctuations form a strong turbulent state.Plasma transport takes place due to the strong turbulence to relax the ambient plasma pressure profile so that the plasma pressure and current density are reduced and the ambient magnetic field intensity increases by more than a factor of 2 in the high-β eq region and the field line geometry recovers from tail-like to dipole-like -dipolarization.3

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Entropy antidiffusion instability and formation of a thin current sheet during geomagnetic substorms

Cited by 27 publications

References 21 publications

Comment on “Tail Reconnection Triggering Substorm Onset”

Comment on “Tail Reconnection Triggering Substorm Onset”

Near‐Earth thin current sheets and Birkeland currents during substorm growth phase

Physics of Substorm Growth Phase, Onset, and Dipolarization

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