57th Annual Meeting of the APS Division of Plasma Physics
Volume 60, Number 19
Monday–Friday, November 16–20, 2015;
Savannah, Georgia
Session DI2: Reconnection from Lab to Space
3:00 PM–5:00 PM,
Monday, November 16, 2015
Room: Chatham Ballroom C
Chair: Paul Cassak, West Virginia University
Abstract ID: BAPS.2015.DPP.DI2.1
Abstract: DI2.00001 : The Magnetospheric Multiscale Mission: New Data on Magnetic Reconnection
3:00 PM–3:30 PM
Preview Abstract
Abstract
Author:
James Burch
(Southwest Research Institute)
The Magnetospheric
Multiscale (MMS) mission was launched on March 12, 2015 into its Phase 1
elliptical orbit with apogee at 12 Earth radii (R$_{\mathrm{E}})$. The
baseline science goal for MMS is to \textit{Understand the microphysics of magnetic reconnection by determining the kinetic processes occurring in the electron diffusion region that are responsible for collisionless magnetic reconnection, especially how reconnection is initiated. }In priority order, MMS will address
three specific objectives: (1) Determine the role played by electron
inertial effects and turbulent dissipation in driving magnetic reconnection
in the electron diffusion region; (2) Determine the rate of magnetic
reconnection and the parameters that control it. (3) Determine the role
played by ion inertial effects in the physics of magnetic reconnection.
During the six months of commissioning following launch, all of the
instruments on the four spacecraft were made fully operational. Beginning on
September 1, 2015 the spacecraft began their first scan of the dayside
magnetopause in a tetrahedral formation with separations of 160 km. During
Phase 1 the separation will be reduced in steps to 10 km and then adjusted
to the separation that is judged to be optimum for reconnection studies. A
second scan of the dayside magnetopause will be conducted at this optimum
separation. Then apogee will be raised to 25 R$_{\mathrm{E}}$ for
a scan of the magnetotail with separations variable from 30 km to 400 km.
Throughout the mission the payload will be operated at its maximum data
rate, which is sufficient to investigate reconnection down to approximately
the electron diffusion length scale with full 3D plasma electron
distributions obtained in 30 ms, ion distributions at 150 ms, and magnetic
and electric fields at 1 ms resolution. 3D plasma and energetic ion
composition an energetic electron measurements along with plasma waves will
also be made. The spacecraft potential is maintained below $+$4V by an ion
emitter. Because of the large amount of data and the downlink limitations,
only a few per cent of data at the highest rates can be sent to the ground.
An on-board data selection system, supplemented by a Scientist-in-the Loop
(SITL) system will be used to obtain the best segments of high-rate data for
reconnection studies. Results from the first three months of Phase 1 will be
presented in this paper.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2015.DPP.DI2.1