Overcoming Uncertainties in the Relation between Source and Aurora

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Unsolved Problems in Magnetospheric Physics Scarborough, UK, 06-12 September 2015 Overcoming Uncertainties in the Relation between Source and Aurora Gerhard Haerendel Max Planck Institute for Extraterrestrial Physics, Garching,Germany 07 September 2015

Principles Two principles govern structured auroral arcs: Arcs are generated to help maximizing the energy dumping from the magnetosphere. Structured auroral arcs derive their energy from the release of magnetic shear stresses. 07 September 2015 Overcoming uncertainties 2

A Classification Scheme Forces: (1) Pressure gradient (2) Inertial forces/flow braking 3) Magnetic shear or normal stresses Energy extraction: (a) Release of previously stored free energy (b) Contemporary build-up and release Energy conversion mechanisms: (α) Post-acceleration by parallel potential drops (β) Energy dumping in topside ionosphere (α) is realized when the forces act against ionospheric friction (β) dominates flow braking events 07 September 2015 Overcoming uncertainties 3

Arc Classification Nine arc types 07 September 2015 Overcoming uncertainties 4

The Case of Embedded Arcs Pressure gradient, release of stored shear stresses, and energy conversion in parallel potential drops. 07 September 2015 Overcoming uncertainties 5

Embedded Arcs FAST Overflight [Haerendel et al. 2012] Upward current and embedded arcs 2 2 Comparing the released energy flux B u B d Rw W tot with the energy conversion 2 J 2 0 0 rate in the arc W arc provided oportunity to check quantitatively the 2 K warc implications of the postulated spontaneous erosion of shear stresses against the measured quantities, as for 1/ 2 instance arc width warc ( RW K) and erosion speed: v n w arc / arc, with no conflicting results. 07 September 2015 Overcoming uncertainties 6

The Environment of Embedded Arcs The plasma entering the magnetosphere continues along the auroral oval. Field-aligned currents of Type II [Boström 1964,1975] are related to the shear stresses driving the convection. Pressure gradient is the driving force storing the energy that is released by the arc [Haerendel 2007]: j B 2 B ion 2 gen p B gen d B However, Vasyliunas [1970] claims that pressure gradients can drive only Region 2 currents, i.e. downward in the evening because of the outward increasing flux tube volume. On the other hand, Fujii et al. [1994] find that the Region 1 current carries at best a net current of 25%. 75% are balanced Type II currents. Does the pressure on the poleward side decrease faster than the flux tube volume increases? 07 September 2015 Overcoming uncertainties 7

The Case of Auroral Streamers Magnetic stresses?, immediate release, energy dumping into ionosphere 07 September 2015 Overcoming uncertainties 8

Auroral Streamers Auroral streamers emerge on the polar cap from poleward boundary intensifications (PBIs) preceding substorm onset and may play a role in the trigger of substorms [Nishimura et al. 2010]. Measurements with the SuperDARN radar [Gallardo- Lacourt et al 2014] confirm an equatorward flow located just to the east of the visible streamer. This suggests a transport of new plasma across the polar cap boundary into the plasma sheet [Nishimura et al. 2010]. Polar cap patches arriving from the dayside may be precursors [Nishimura et al. 2013]. Streamers also appear inside the auroral oval during a substorm as result of plasma entry [Nakamura et al. 1993; Henderson et al. 1994; Haerendel 2015]. The equatorward flow indicates that work is done against ionospheric friction! 07 September 2015 Overcoming uncertainties 9

The Driver of Auroral Streamers Is the streamer flow driven by the contraction of flux tubes originally extending to the distant neutral line and after near-earth reconnection are drastically shortened [Mende et al. 2011]? Or are the streamers bubbles of lower plasma pressure as suggested by Nakamura et al. [2001]? Do the diverted external currents connect to field-aligned currents extending into the ionosphere? Lobe pressure and magnetic tensions join in driving the bubble plasma. However, does the plasma also do work on the ionospheric plasma as the equatorward flow suggests? Kauristie et al. [2000] suggest flow braking and vortex fomation. The long duration and propagation of the streamers rather suggest a persistent flow channel [Haerendel 2015]. But what is the driver? 07 September 2015 Overcoming uncertainties 10

By Contrast: Sun-aligned Arcs Sun-aligned arcs appear during IMF Bz >0. They are related with anti-sunward flow. Drag forces (flow braking) exerted by the mantle flow, after lobe reconnection, are transferred to the ionosphere by magnetic shear stresses and do work against the ionospheric friction [Bonnell et al. 1999]. Build-up rather than release of shear stresses! 07 September 2015 Overcoming uncertainties 11

Two Sources of Kinetic Alfvén Waves Kinetic Alfvén waves are ubiquitous, but rarely is their origin identified. 07 September 2015 Overcoming uncertainties 12

Low-altitude Source: Scale-breaking The Alfvénic arcs are embedded in an eastward flow region flanked by balanced FACs. Small-scale electromagnetic structures (inertial Alfvén waves) are developing from the primary energy inflow by multiple reflections in the ionospheric Alfvén resonator and scalebreaking [Haerendel and Frey 2014]. The mechanism may be phase mixing [Lysak and Song 2008], tearing instabilities of thin current sheets [Seyler 1990], or turbulent cascade [Chaston et al. 2008] 07 September 2015 Overcoming uncertainties 13

High-altitude Source: The Stop Layer The stop layer [Haerendel 2015]: The flow from the central plasma sheet is stopped abruptly (within about 1 c/ω pi ). The momentum extracted from the ions by the electric polarization field is taken up by the magnetic field generated by the Hall current along the stop layer. The smallscale structure arises from balancing ion inflow with electron Hall drift. Each structure is flanked by a pair of anti-parallel FACs and is the source of a downward propagating kinetic Alfvén wave. 07 September 2015 Overcoming uncertainties 14

Summary Two principles govern the generation of structured auroral arcs: Maximiziation of energy dumping and release of magnetic stresses. Seven criteria are used for classification of the underlying processes related to forces, energy extraction, and conversion mechanisms. They are meant as a means to identify the source-arc relations. Classification of 9 types of arcs shows the important roles of flow braking, immediate energy release, and post-acceleration. The closer inspection of two examples, embedded arcs and auroral streamers, demonstrate the still existing uncertainties about the driving forces. Two sources of kinetic Alfvén waves are to be found in the ionospheric Alfvén resonator and at the inner boundary of the tail during substorms. 07 September 2015 Overcoming uncertainties 15

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