Sun  ID: 11795

MMS L-1 Media Briefing

Released on March 11, 2015
On March 12 from Cape Canaveral Florida, NASA is scheduled to launch the Magnetospheric Multiscale, or MMS, mission, which will provide unprecedented detail on a phenomenon called magnetic reconnection. The process of reconnection involves the explosive release of energy when the magnetic fields around Earth connect and disconnect. These fields help protect Earth from harmful effects of solar storms and cosmic rays. Magnetic reconnection also occurs throughout the universe and can accelerate particles up to nearly the speed of light.


By studying reconnection in this local, natural laboratory, MMS helps us understand reconnection elsewhere as well, such as in the atmosphere of the Sun and other stars, in the vicinity of black holes and neutron stars, and at the boundary between our solar system’s heliosphere and interstellar space.


MMS consists of four identical observatories that will provide the first three-dimensional view of magnetic reconnection. The four MMS observatories will fly through reconnection regions in a tight formation in well under a second, so key sensors on each spacecraft are designed to measure the space environment at rates faster than any previous mission.



For additional visuals regarding the MMS mission and science, please see our MMS Pre-launch Gallery.




Briefing participants include:


Jeff Newmark, interim director, Heliophysics Division NASA Headquarters, Washington

Jim Burch, principal investigator, MMS instrument suite science team Southwest Research Institute, San Antonio

Roy Torbert, MMS FIELDS investigation lead University of New Hampshire, Durham, New Hampshire

Craig Pollock, lead co-investigator, MMS Fast Plasma Investigation Goddard Space Flight Center, Greenbelt, Maryland

Paul Cassak, associate professor West Virginia University, Morgantown

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Heliophysics is the study of the physical domain dominated by the Sun and its extension into space—the heliosphere. This physical domain includes our Sun and the space environments of Earth and other planets, and stretches out to the region of interstellar space. The Sun’s variability and extended atmosphere drive some of the greatest changes in our local magnetic environment, affecting our own atmosphere, ionosphere, and our climate. Heliophysics is also the underlying science of space weather. Space weather directly affects the safety of humans in space and on Earth by influencing the operation of electrical power grids, communications and navigation systems, gas and oil pipelines, and spacecraft electronics and orbital dynamics.

Credit: NASA/GSFC


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Using the entire fleet of solar, heliospheric, magnetospheric, ionospheric, and upper atmospheric missions, and data from planetary spacecraft, NASA operates the Heliophysics System Observatory (HSO) as a distributed observatory to discover the larger scale and/or

coupled processes at work throughout the complex system that makes up our space environment. This distributed observatory has flexibility and capabilities that evolve with each new mission launched. In addition to supplying valued science data, many operating HSO missions provide key observations used to predict space weather. The HSO is a continuously evolving fleet, with each mission providing key inputs from unique vantage points.

Credit: NASA


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MMS solves the mystery of how magnetic fields around Earth connect and disconnect, explosively releasing energy via a process known as magnetic reconnection. MMS consists of four identical spacecraft that will provide the first three-dimensional views of this fundamental process that occurs throughout our universe. MMS uses Earth’s protective magnetic space environment, the magnetosphere, as a natural laboratory to directly observe how it interacts with the sun’s extended magnetic field, which can result in reconnection. The four MMS spacecraft fly in varying formations through reconnection regions in well under a second, so key sensors on each MMS spacecraft have been designed to take certain measurements of the space environment 100 times faster than any previous mission. Like stretched rubber bands, magnetic fields store energy that is released explosively when the field lines are broken during reconnection. Unlike rubber bands, reconnection can drive particles to nearly the speed of light. Credit: NASA/GSFC


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Electron currents in reconnection simulation.

Credit:Dr. Homa Karimabadi, UCSD


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MMS orbits viewed from above north pole.

Credit: SwRI


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Video of MMS in tetrahedron formation

Credit: NASA/GSFC


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Animation and visualization of MMS orbit and tetrahedron formation

Credit: NASA/GSFC/CIL


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Animation of MMS from separation through boom deployment.

Credit: NASA/GSFC/CIL


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Magnetic reconnection in the Earth's magnetosphere.

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Images from simulations of magnetic reconnection at 100, 000 km, 500 km, and 100 km.

Credit: NASA


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Images of FPI - Dual Plasma Spectrometers

Credit: NASA


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The first four completed DES.

Credit: NASA


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One of the MMS spacecraft in a thermal vacuum chamber, as another waits for its turn.

Credit: NASA


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The four MMS spacecraft in the clean room at NASA's Goddard Space Flight Center.

Credit: NASA


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Watch this video on the NASAexplorer YouTube channel.

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The MMS spacecraft ready for encapsulation.

Credit: NASA

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Animation depicting MMS boom deployment.

Credit: NASA/GSFC/CIL

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Deployed ADP Boom.

Credit: ATK Systems

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Visualization of magnetic reconnection.

Credit: Paul Cassak

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Data of the sun from NASA's Solar Dynamics Observatory (SDO) showing magnetic reconnection in the sun's atmosphere. The image shows the material at 18 million degrees (Fahrenheit). This material, in the plasma state, tends to follow magnetic field lines, so we effectively see the shapes of magnetic field lines. In this movie, we see the magnetic fields pinch together and move out the top and bottom, which is a tell-tale signature of magnetic reconnection. This shows that reconnection happens in the solar atmosphere. Half way through, data from NASA's RHESSI satellite are overlaid on the SDO data. RHESSI shows the plasma that is at 200 million degrees, revealing that the hottest material is located where the magnetic fields move away from the reconnection site. This shows how important reconnection is for producing energetic charged particles. No audio.

Credit: NASA/GSFC

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Data of the sun from NASA's Solar Dynamics Observatory (SDO) showing magnetic reconnection in the sun's atmosphere. The image shows the material at 18 million degrees (Fahrenheit). This material, in the plasma state, tends to follow magnetic field lines, so we effectively see the shapes of magnetic field lines. In this movie, we see the magnetic fields pinch together and move out the top and bottom, which is a tell-tale signature of magnetic reconnection. This shows that reconnection happens in the solar atmosphere. Half way through, data from NASA's RHESSI satellite are overlaid on the SDO data. RHESSI shows the plasma that is at 200 million degrees, revealing that the hottest material is located where the magnetic fields move away from the reconnection site. This shows how important reconnection is for producing energetic charged particles.

Credit: Paul Cassak and Michael Shay.

 

Related

MMS L-2 Prelaunch News Conference

Credits

Please give credit for this item to:
NASA's Goddard Space Flight Center

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Mission:
Magnetospheric Multiscale (MMS)

Keywords:
NASA Science >> Sun
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