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A Simulated View of a Substorm: An IMAGE Perspective

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1 A Simulated View of a Substorm: An IMAGE Perspective
J. L. Green, D. L. Gallagher, S. F. Fung, M.-C. Fok, T. E. Moore, G. R. Gladstone, G. R. Wilson, J. D. Perez, W. Calvert, P. H. Reiff International Conference on Substorms-4 Lake Hamana, Japan March 12, 1998

2 Abstract The Imager for Magnetopause-to-Aurora Global Exploration (IMAGE) is NASA's first medium-sized Explorer mission and is scheduled to be launched in January The overall science objective of IMAGE is to determine the global response of the magnetosphere to changing conditions in the solar wind. The science payload for IMAGE consists of instrumentation for obtaining images of plasma regions in the Earth's magnetosphere. The four types of imaging techniques used by IMAGE are: neutral atom imaging (NAI), far ultraviolet imaging (FUV), extreme ultraviolet imaging (EUV), and radio plasma imaging (RPI). The IMAGE instruments will make concurrent global-scale images providing researchers with an opportunity to readily observe the structure and dynamics of the plasmasphere, ring current, aurora, geocorona, and the magnetopause within a substorm. The IMAGE mission is being designed to generate browsable images from each of its instruments on approximately a 4 minute time scale. Using appropriate models we will simulate what users of IMAGE data should expect to see during a substorm. It is anticipated that IMAGE should be able to illuminate the global development of magnetospheric substorm dynamics.

3 Mission Science Objectives
What are the dominant mechanisms for injecting plasma into the the magnetosphere on substorm and magnetic storm time scales? What is the directly driven response to the magnetosphere to solar wind changes? How and where are magnetospheric plasmas energized, transported, and subsequently lost during storms and substorms? The IMAGE mission addresses these objectives in unique ways using imaging techniques.

4 IMAGE Team Members Principal investigator: Dr. James L. Burch, SwRI
U.S. Co-Investigators: Prof. K. C. Hsieh & Dr. B. R. Sandel, University of Arizona Dr. J. L. Green & Dr. T. E. Moore, Goddard Space Flight Center Dr. S. A. Fuselier, Lockheed Palo Alto Research Laboratory Drs. S. B. Mende, University of California, Berkeley Dr. D. L. Gallagher, Marshall Space Flight Center Prof. D. C. Hamilton, University of Maryland Prof. B. W. Reinisch, University of Massachusetts, Lowell Dr. W. W. L. Taylor, Raytheon STX Corporation Prof. P. H. Reiff, Rice University Drs. D. T. Young, C. J. Pollack, Southwest Research Institute Dr. D. J. McComas, Los Alamos National Laboratory Dr. D. G. Mitchell, Applied Physic Labortory, JHU

5 IMAGE Foreign Co-Is Foreign Co-Investigators
Dr. P. Wurz & Prof. P. Bochsler, University of Bern, Switzerland Prof. J. S. Murphree, University of Calgary, Canada Prof. T. Mukai, ISAS, Japan Dr. M. Grande, Rutherford Appleton Laboratory, U.K. Dr. C. Jamar, University of Liege, Belgium Dr. J.-L. Bougeret, Observatoire de Paris, Meudon Dr. H. Lauche, Max-Planck-Institut fur Aeronomie

6 Other Team Members Participating Scientist:
Dr. G. R. Wilson, University of Alabama Huntsville Drs. A. L. Broadfoot & C. C. Curtis, University of Arizona Dr. J. D. Perez, Auburn University L. Cogger, University of Calgary, Canada Drs. R. F. Benson & S. F. Fung, Goddard Space Flight Center Dr. W. Calvert, University of Massachusetts, Lowell Drs. A. G. Ghielmetti, Y. T. Chiu, M. Schulz, & E. G. Shelley, Lockheed Dr. J. M. Quinn, University of New Hampshire Dr. J. Spann, Marshall Space Flight Center Prof. J.-C. Gerard, University of Liege, Belgium Dr. G. R. Gladstone, Southwest Research Institute Dr. D. L. Carpenter, Stanford University

7 IMAGE Instruments Neutral Atom Imagers FUV Imagers EUV Imager
High Energy Neutral Atom (HENA) imager Medium Energy Neutral Atom (MENA) imager Low Energy Neutral Atom (LENA) imager FUV Imagers Spectrographic Imager (SI) Geocorona (GEO) imager Wideband Imaging Camera (WIC) EUV Imager Extreme Ultra-Violet (EUV) imager Radio Sounder Radio Plasma Imager (RPI)

8 IMAGE Data and Orbit Orbit:90° inclination, 7 RE x 1,000 km altitudeimulations illustrate instrument measurements for the magnetic cloud event of October 18-20, 1995 Actual Dst measurement shows the storm sequence Red dots show spacecraft location (top) and state of the ring current (bottom)

9 Neutral Atom Imaging (NAI)
Earth’s Geocorona (cold neutral hydrogen) and Ring Current interact through charge exchange During quiet times (top) the NAI fluxes are low During storm time (bottom) NAI flux enhancements allow the tracking of storm development (spatial and temporal)

10 High Energy Neutral Atom (HENA)
HENA Observations Neutral atom composition and energy-resolved images over three energy ranges: keV Measure Requirements FOV: 90°x 120° Angular Resolution: 4°x 4° Energy Resolution (E/E): 0.8 Sensitivity: Effective area 1 cm**2 Storm/substorm Observations Image Time: 2 minutes generating 720 images/day Derived Quantities: Neutral atom image of composition and energy of the Ring Current and near-Earth Plasma Sheet HENA/MENA instrument data combined to make a provisional Dst index Plasma Sheet and Ring Current injection dynamics, structure, shape and local time extent

11 Medium Energy Neutral Atom (MENA)
MENA Observations Neutral atom composition and energy-resolved images over three energy ranges: 1-30 keV Measure Requirements FOV: 90°x 107° Angular Resolution:4°x 8° Energy Resolution (E/E): 0.8 Sensitivity: Effective area 1 cm**2 Storm/substorm Observations Image Time: 2 minutes generating 720 images/day Derived Quantities: Neutral atom image of composition and energy of the Ring Current and near-Earth Plasma Sheet HENA/MENA instrument data combined to make a provisional Dst index Plasma Sheet and Ring Current injection dynamics, structure, shape and local time extent

12 Low Energy Neutral Atom (LENA)
High Altitude LENA Observations Neutral atom composition and energy-resolved images over three energy ranges: eV Measure Requirements Angular Resolution: 8°x 8° Energy Resolution (E/E): 0.8 Composition: distinguish H and O in ionospheric sources, interstellar neutrals and solar wind. Sensitivity: Effective area > 1 cm**2 Storm/substorm Observations Image Time: 2 minutes (resolve substorm development) generating 720 images/day Derived Quantities: Neutral atom composition and energy of the Auroral/Cleft ion fountain Ionospheric outflow Low Altitude

13 Spectrographic Imager (SI)
SI Observations Far ultraviolet imaging of the aurora Image full Earth from apogee Measurement Requirement FOV: 15°x 15° for aurora (image full Earth from apogee), Spatial Resolution: 90 km Spectral Resolution (top): Reject nm and select nm electron aurora emissions. Spectral Resolution (bottom): nm Storm/substorm Observations Image Time: 2 minutes generating 720 images/day Derived Quantities Structure and intensity of the electron aurora (top) Structure

14 Extreme Ultra-Violet (EUV) imager
EUV Observations 30.4 nm imaging of plasmasphere He+ column densities Measure Requirements FOV: 90°x 90° (image plasmasphere from apogee) Spatial Resolution: 0.1 Earth radius from apogee Storm/substorm Observations Image Time: 10 minutes generating 144 images/day Derived Quantities: Plasmaspheric density structure and plasmaspheric processes

15 Geocorona (GEO) Imager
GEO Observations Far ultraviolet imaging of the Earth’s Geocorona Measurement Requirement FOV: 1° x 360° for Geocorona Spatial Resolution: 90 km Spectral Resolution:Lyman alpha nm Storm/substorm Observations Image Time: 2 minutes generating 720 images/day Derived Quantities Integrated line-of-sight density map of the Earth’s Geocorona Not shown in the IMAGE Movie Image at left from Rairden et al., 1986

16 Radio Plasma Imager (RPI)
RPI Observations Remote sensing of electron density structure and magnetospheric boundary locations Measure Requirements Density range: **5 cm-3 (determine electron density from inner plasmasphere to magnetopause) Spatial resolution: 500 km (resolve density structures at the magnetopause and plasmapause) Storm/substorm Observations Image Time: 3 minute (resolve changes in boundary locations) generating 480 plasmagrams/day Quantity Simulated is an RPI “echo map” Illustrates spatial location and intensity of return echoes (plotted as ray miss distance) Doppler measurement (not shown) provides key information on boundary motion Echoes from a large scale surface waves on the magnetopause

17 Simulated RPI Plasmagram
RPI browse product data will produce plasmagrams Echoes shown in solid line, density features in dashed line. Derived Quantities from Plasmagrams include: Distance to Magnetopause, Plasmapause, Polar Cusp (when observed) Magnetospheric shape (with model), structure, gross irregularities Storm conditions from a plasma/radio wave perspective

18 Summary IMAGE will be launched in January 2000 just before solar maximum All instruments on IMAGE will provide unique global images of magnetospheric storm & substorm dynamics Proton and Electron Aurora Ring Current distribution and a provisional Dst (see Jorgensen et. al, 1997) Electron density structures and magnetospheric boundary locations (plasmapause, cusp, etc.) Geocorona and He+ plasmaspheric distributions For more details see ->

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