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1. TRICE‐2/SuperDARN Observations and Comparison With the Associated MMS Magnetopause Crossing.

Author

Trattner, K. J., Fuselier, S. A., Kletzing, C. A., Bonnell, J. W., Bounds, S. R., Petrinec, S. M., Sawyer, R. P., Yeoman, T. K., Ergun, R. E., and Burch, J. L.

Subjects
MAGNETOPAUSE, SOLAR cycle, ROCKETS (Aeronautics), BOUNDARY layer (Aerodynamics), ION beams, ION energy, ION bombardment
Abstract

Two sounding rockets, designated TRICE‐2, were launched on 8 December 2018 into the northern cusp region. The two rockets were designated the high‐ and low‐flyers, respectively, and launched 2 min apart to investigate cusp structures, specifically their spatial or temporal nature. 2 hr prior to the cusp encounter by the TRICE‐2 rockets, the MMS satellites, located in the magnetopause boundary layer, observed switching ion beams under very similar IMF conditions as later observed by TRICE‐2. The observed ion beam switch in the boundary layer defined the location of the primary dayside X‐line. Both, TRICE‐2 and MMS, also observed the signatures of multiple X‐lines at the magnetopause, overlapping ion‐energy dispersions in the cusp and counterstreaming ion beams in the magnetopause boundary layer, respectively. In addition to the TRICE‐2 cusp observations, ionospheric convection patterns from the SuperDARN radar are used to explain the vastly different cusp ion signatures observed by the TRICE‐2 rockets. While the high‐flyer rocket progressed north through the center of the cusp, the low‐flyer rocket drifted off to the east and crossed into the dusk convection cell, traveling perpendicular to the ionospheric convection direction before reaching the poleward oriented section of the convection cell also observed by the high‐flyer counterpart. Key Points: TRICE‐2 cusp ion dispersions are explained using the different magnetic foot points of the rockets through the ionospheric convection cellsTRICE‐2 cusp crossing occurred 2 hr after an MMS magnetopause crossing during similar IMF conditionsOverlapping cusp ion energy dispersions result from multiple magnetopause reconnection locations in agreement with MMS observations [ABSTRACT FROM AUTHOR]

Published
2024
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2. The Electric and Magnetic Field Instrument Suite and Integrated Science (EMFISIS) on RBSP

Author

Kletzing, C. A., Kurth, W. S., Acuna, M., MacDowall, R. J., Torbert, R. B., Averkamp, T., Bodet, D., Bounds, S. R., Chutter, M., Connerney, J., Crawford, D., Dolan, J. S., Dvorsky, R., Hospodarsky, G. B., Howard, J., Jordanova, V., Johnson, R. A., Kirchner, D. L., Mokrzycki, B., Needell, G., Odom, J., Mark, D., Pfaff, R., Jr., Phillips, J. R., Piker, C. W., Remington, S. L., Rowland, D., Santolik, O., Schnurr, R., Sheppard, D., Smith, C. W., Thorne, R. M., Tyler, J., Fox, Nicola, editor, and Burch, James L., editor

Published
2014
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3. The FIELDS Instrument Suite on MMS: Scientific Objectives, Measurements, and Data Products

Author

Torbert, R. B., Russell, C. T., Magnes, W., Ergun, R. E., Lindqvist, P.-A., LeContel, O., Vaith, H., Macri, J., Myers, S., Rau, D., Needell, J., King, B., Granoff, M., Chutter, M., Dors, I., Olsson, G., Khotyaintsev, Y. V., Eriksson, A., Kletzing, C. A., Bounds, S., Anderson, B., Baumjohann, W., Steller, M., Bromund, K., Le, Guan, Nakamura, R., Strangeway, R. J., Leinweber, H. K., Tucker, S., Westfall, J., Fischer, D., Plaschke, F., Porter, J., and Lappalainen, K.

Published
2016
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4. The Electron Drift Instrument for MMS

Author

Torbert, R. B., Vaith, H., Granoff, M., Widholm, M., Gaidos, J. A., Briggs, B. H., Dors, I. G., Chutter, M. W., Macri, J., Argall, M., Bodet, D., Needell, J., Steller, M. B., Baumjohann, W., Nakamura, R., Plaschke, F., Ottacher, H., Hasiba, J., Hofmann, K., Kletzing, C. A., Bounds, S. R., Dvorsky, R. T., Sigsbee, K., and Kooi, V.

Published
2016
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5. The FIELDS Instrument Suite on MMS: Scientific Objectives, Measurements, and Data Products

Author

Torbert, R. B., primary, Russell, C. T., additional, Magnes, W., additional, Ergun, R. E., additional, Lindqvist, P.-A., additional, LeContel, O., additional, Vaith, H., additional, Macri, J., additional, Myers, S., additional, Rau, D., additional, Needell, J., additional, King, B., additional, Granoff, M., additional, Chutter, M., additional, Dors, I., additional, Olsson, G., additional, Khotyaintsev, Y. V., additional, Eriksson, A., additional, Kletzing, C. A., additional, Bounds, S., additional, Anderson, B., additional, Baumjohann, W., additional, Steller, M., additional, Bromund, K., additional, Le, Guan, additional, Nakamura, R., additional, Strangeway, R. J., additional, Leinweber, H. K., additional, Tucker, S., additional, Westfall, J., additional, Fischer, D., additional, Plaschke, F., additional, Porter, J., additional, and Lappalainen, K., additional

Published
2016
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6. The Electron Drift Instrument for MMS

Author

Torbert, R. B., primary, Vaith, H., additional, Granoff, M., additional, Widholm, M., additional, Gaidos, J. A., additional, Briggs, B. H., additional, Dors, I. G., additional, Chutter, M. W., additional, Macri, J., additional, Argall, M., additional, Bodet, D., additional, Needell, J., additional, Steller, M. B., additional, Baumjohann, W., additional, Nakamura, R., additional, Plaschke, F., additional, Ottacher, H., additional, Hasiba, J., additional, Hofmann, K., additional, Kletzing, C. A., additional, Bounds, S. R., additional, Dvorsky, R. T., additional, Sigsbee, K., additional, and Kooi, V., additional

Published
2016
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7. Plasma Wave Measurements from the Van Allen Probes

Author

Hospodarsky, George B., primary, Kurth, W. S., additional, Kletzing, C. A., additional, Bounds, S. R., additional, Santolík, O., additional, Thorne, Richard M., additional, Li, Wen, additional, Averkamp, T. F., additional, Wygant, J. R., additional, and Bonnell, J. W., additional

Published
2016
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9. TRICE‐2 Rocket Observations in the Low‐Altitude Cusp: Boundaries and Comparisons With Models.

Author

Petrinec, S. M., Kletzing, C. A., Bounds, S. R., Fuselier, S. A., Trattner, K. J., and Sawyer, R. P.

Subjects
ELECTROSTATIC analyzers, BOUNDARY layer (Aerodynamics), ROCKET launching, MAGNETIC reconnection, ELECTRODYNAMICS
Abstract

The launch of the Twin Rockets to Investigate Cusp Electrodynamics‐2 (TRICE‐2) took place on the morning of 08 December 2018. The two rockets of this campaign each sampled the low‐altitude Northern Hemisphere cusp region at approximately the apex of each rocket's trajectory (1,042 and 757 km for the High flyer and Low flyer, respectively). Ion and electron electrostatic analyzers (ESAs) on board each rocket measured in situ particle populations throughout the flights. Energy‐flux spectrograms of ions and electrons from each ESA clearly show the passage of each rocket through the cusp region. This work examines the locations of these entrance/exit points in relation to cusp models as provided in and compiled from the published literature, along with a discussion of model variables that have been optimized to best fit the cusp region boundary sampling locations by TRICE‐2. The results of this study set the stage for understanding the upcoming NASA Small Explorer Tandem Reconnection and Cusp Electrodynamics Reconnaissance Satellites orbital plane intersections with (i.e., "trajectory cuts" through) the cusp region. Key Points: The low‐altitude cusp region was directly sampled by instruments onboard the two Twin Rockets to Investigate Cusp Electrodynamics‐2 rocketsCusp models have been compiled from published studies, with free parameters representing the low‐latitude boundary layer and mantleCusp model free parameters have been optimized to best match the observed cusp region location [ABSTRACT FROM AUTHOR]

Published
2023
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10. The Electric and Magnetic Field Instrument Suite and Integrated Science (EMFISIS) on RBSP

Author

Kletzing, C. A., Kurth, W. S., Acuna, M., MacDowall, R. J., Torbert, R. B., Averkamp, T., Bodet, D., Bounds, S. R., Chutter, M., Connerney, J., Crawford, D., Dolan, J. S., Dvorsky, R., Hospodarsky, G. B., Howard, J., Jordanova, V., Johnson, R. A., Kirchner, D. L., Mokrzycki, B., Needell, G., Odom, J., Mark, D., Pfaff, Jr., R., Phillips, J. R., Piker, C. W., Remington, S. L., Rowland, D., Santolik, O., Schnurr, R., Sheppard, D., Smith, C. W., Thorne, R. M., and Tyler, J.

Published
2013
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12. TRICE 2 Observations of Low‐Energy Magnetospheric Ions Within the Cusp

Author

Sawyer, R. P., primary, Fuselier, S. A., additional, Kletzing, C. A., additional, Bonnell, J. W., additional, Roglans, R., additional, Bounds, S. R., additional, Kim, M. J., additional, Vines, S. K., additional, Cairns, I. H., additional, Moser, C., additional, LaBelle, J., additional, Moen, J. I., additional, Trattner, K. J., additional, Petrinec, S. M., additional, Burch, J. L., additional, Giles, B. L., additional, and George, D., additional

Published
2021
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13. Current Closure in the Auroral Ionosphere: Results From the Auroral Current and Electrodynamics Structure Rocket Mission

Author

Kaeppler, S. R., primary, Kletzing, C. A., additional, Bounds, S. R., additional, Gjerloev, J. W., additional, Anderson, B. J., additional, Korth, H., additional, LaBelle, J. W., additional, Dombrowski, M. P., additional, Lessard, M., additional, Pfaff, R. F., additional, Rowland, D. E., additional, Jones, S., additional, and Heinselman, C.J., additional

Published
2013
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14. The Electric and Magnetic Field Instrument Suite and Integrated Science (EMFISIS) on RBSP

Author

Kletzing, C. A., primary, Kurth, W. S., additional, Acuna, M., additional, MacDowall, R. J., additional, Torbert, R. B., additional, Averkamp, T., additional, Bodet, D., additional, Bounds, S. R., additional, Chutter, M., additional, Connerney, J., additional, Crawford, D., additional, Dolan, J. S., additional, Dvorsky, R., additional, Hospodarsky, G. B., additional, Howard, J., additional, Jordanova, V., additional, Johnson, R. A., additional, Kirchner, D. L., additional, Mokrzycki, B., additional, Needell, G., additional, Odom, J., additional, Mark, D., additional, Pfaff, R., additional, Phillips, J. R., additional, Piker, C. W., additional, Remington, S. L., additional, Rowland, D., additional, Santolik, O., additional, Schnurr, R., additional, Sheppard, D., additional, Smith, C. W., additional, Thorne, R. M., additional, and Tyler, J., additional

Published
2013
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17. Erratum to: The Electron Drift Instrument for MMS

Author

Torbert, R. B., Vaith, H., Granoff, M., Widholm, M., Gaidos, J. A., Briggs, B. H., Dors, I. G., Chutter, M. W., Macri, J., Argall, M., Bodet, D., Needell, J., Steller, M. B., Baumjohann, W., Nakamura, R., Plaschke, F., Ottacher, H., Hasiba, J., Hofmann, K., Kletzing, C. A., Bounds, S. R., Dvorsky, R. T., Sigsbee, K., and Kooi, V.

Published
2016
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18. An Experimental and Numerical Investigation into the Thermal Behavior of the Pressure Die Casting Process

Author

Bounds, S., Davey, K., and Hinduja, S.

Subjects
Production engineering research -- Analysis, Pressure -- Analysis, Die castings -- Analysis, Heat-transfer media -- Analysis, Cooling -- Analysis, Engineering and manufacturing industries, Science and technology
Abstract

The modeling of the pressure die casting process generally requires the specification of heat transfer coefficients at the surfaces of the die. The coefficients at the cavity-casting interface and at the cooling channel surfaces are of particular importance. In order to provide estimates for these heat transfer coefficients, the behavior of a specifically designed zinc alloy casting is investigated using a three dimensional thermal model whose predictions are supported by experimentally obtained results. The numerical model uses the boundary element method for the dies, as surface temperatures are of particular importance, and the finite element method for the casting, where the nonlinear material behavior makes this technique suitable. The experimental data comprises of thermocouple measurements of both die, casting, and coolant temperatures for three sets of operating conditions. These measurements are complemented by qualitative data of casting defects caused by incomplete solidification and thermal imaging temperature measurements. An experimental technique for obtaining average heat transfer coefficients for the casting-die interface is presented. Although the technique circumvents the need to place thermocouples in the casting and provides average heat transfer coefficients of sufficient accuracy for modeling purposes, it is not sufficiently responsive to provide accurate transient information. The presence of coolant boiling is detected by its effect on the rates of heat extraction. Heat transfer coefficients are determined for the cooling channels using a boiling model. Comparison between predicted and experimental rates of heat transfer to the coolant support the need for a boiling model. Good agreement is obtained between experimental and numerical predictions.

Published
2000

19. Strong Magnetic Field Fluctuations within Filamentary Auroral Density Cavities Interpreted as VLF Saucer Sources

Author

Knudsen, D. L, Kabirzadeh, R, Burchill, J. K, Pfaff, Robert F, Wallis, D. D, Bounds, S. R, Clemmons, J. H, and Pincon, J.-L

Subjects
Space Sciences (General)
Abstract

The Geoelectrodynamics and Electro-Optical Detection of Electron and SuprathermalIon Currents (GEODESIC) sounding rocket encountered more than 100 filamentary densitycavities associated with enhanced plasma waves at ELF (3 kHz) and VLF (310 kHz)frequencies and at altitudes of 800990 km during an auroral substorm. These cavities weresimilar in size (20 m diameter in most cases) to so-called lower-hybrid cavities (LHCs)observed by previous sounding rockets and satellites; however, in contrast, many of theGEODESIC cavities exhibited up to tenfold enhancements in magnetic wave powerthroughout the VLF band. GEODESIC also observed enhancements of ELF and VLFelectric fields both parallel and perpendicular to the geomagnetic field B0 within cavities,though the VLF E field increases were often not as large proportionally as seen in themagnetic fields. This behavior is opposite to that predicted by previously published theoriesof LHCs based on passive scattering of externally incident auroral hiss. We argue thatthe GEODESIC cavities are active wave generation sites capable of radiating VLF wavesinto the surrounding plasma and producing VLF saucers, with energy supplied by cold,upward flowing electron beams composing the auroral return current. This interpretation issupported by the observation that the most intense waves, both inside and outside cavities,occurred in regions where energetic electron precipitation was largely inhibited orabsent altogether. We suggest that the wave-enhanced cavities encountered by GEODESICwere qualitatively different from those observed by earlier spacecraft because of thefortuitous timing of the GEODESIC launch, which placed the payload at apogee within asubstorm-related return current during its most intense phase, lasting only a few minutes.

Published
2012
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20. Current Closure in the Auroral Ionosphere: Results from the Auroral Current and Electrodynamics Structure Rocket Mission

Author

Kaeppler, S. R, Kletzing, C. A, Bounds, S. R, Gjerloev, J. W, Anderson, B. J, Korth, H, LaBelle, J. W, Dombrowski, M. P, Lessard, M, Pfaff, R. F, Rowland D. E, Jones, S, and Heinselman, C. J

Subjects
Geophysics
Abstract

The Auroral Current and Electrodynamics Structure (ACES) mission consisted of two sounding rockets launched nearly simultaneously from Poker Flat Research Range, AK on January 29, 2009 into a dynamic multiple-arc aurora. The ACES rocket mission was designed to observe electrodynamic and plasma parameters above and within the current closure region of the auroral ionosphere. Two well instrumented payloads were flown along very similar magnetic field footprints, at different altitudes, with small temporal separation between both payloads. The higher altitude payload (apogee 360 km), obtained in-situ measurements of electrodynamic and plasma parameters above the current closure region to determine the input signature. The low altitude payload (apogee 130 km), made similar observations within the current closure region. Results are presented comparing observations of the electric fields, magnetic components, and the differential electron energy flux at magnetic footpoints common to both payloads. In situ data is compared to the ground based all-sky imager data, which presents the evolution of the auroral event as the payloads traversed through magnetically similar regions. Current measurements derived from the magnetometers on the high altitude payload observed upward and downward field-aligned currents. The effect of collisions with the neutral atmosphere is investigated to determine if it is a significant mechanism to explain discrepancies in the low energy electron flux. The high altitude payload also observed time-dispersed arrivals in the electron flux and perturbations in the electric and magnetic field components, which are indicative of Alfven waves.

Published
2012

21. Current Closure in the Auroral Ionosphere: Results from the Auroral Current and Electrodynamics Structure Rocket Mission

Author

Kaeppler, S. R, Kletzing, C. A, Bounds, S. R, Gjerloev, J. W, Anderson, B. J, Korth, H, LaBelle, J. W, Dombrowski, M. P, Lessard, M, Pfaff, R. F, Rowland, D. E, Jones, S, and Heinselman, C. J

Subjects
Astronomy
Abstract

The Auroral Current and Electrodynamics Structure (ACES) mission consisted of two sounding rockets launched nearly simultaneously from Poker Flat Research Range, AK on January 29, 2009 into a dynamic multiple-arc aurora. The ACES rocket mission was designed to observe electrodynamic and plasma parameters above and within the current closure region of the auroral ionosphere. Two well instrumented payloads were flown along very similar magnetic field footprints, at different altitudes, with small temporal separation between both payloads. The higher altitude payload (apogee 360 km), obtained in-situ measurements of electrodynamic and plasma parameters above the current closure region to determine the input signature. The low altitude payload (apogee 130 km), made similar observations within the current closure region. Results are presented comparing observations of the electric fields, magnetic components, and the differential electron energy flux at magnetic footpoints common to both payloads. In situ data is compared to the ground based all-sky imager data, which presents the evolution of the auroral event as the payloads traversed through magnetically similar regions. Current measurements derived from the magnetometers on the high altitude payload observed upward and downward field-aligned currents. The effect of collisions with the neutral atmosphere is investigated to determine it is a significant mechanism to explain discrepancies in the low energy electron flux. The high altitude payload also observed time-dispersed arrivals in the electron flux and perturbations in the electric and magnetic field components, which are indicative of Alfven waves.

Published
2011

23. Ion Layer Separation and Equilibrium Zonal Winds in Midlatitude Sporadic E

Author

Earle, G. D, Kane, T. J, Pfaff, R. F, and Bounds, S. R

Subjects
Geophysics
Abstract

In-situ observations of a moderately strong mid-latitude sporadic-E layer show a separation in altitude between distinct sublayers composed of Fe(+), Mg(+), and NO(+). From these observations it is possible to estimate the zonal wind field consistent with diffusive equilibrium near the altitude of the layer. The amplitude of the zonal wind necessary to sustain the layer against diffusive effects is less than 10 meters per second, and the vertical wavelength is less than 10 km.

Published
2000
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26. The Dipper Satellite: A Medium-Class Explorer Mission to the Threshold of Space

Author

Pfaff, R. F., Jr, Acuna, M, Bounds, S, Hoffman, R, Mahaffy, P, Earle, G, Fesen, C, Heelis, R, Blake, J, Christensen, A, and Clemmons, J

Subjects
Geophysics
Abstract

The Dipper satellite will carry out an unprecedented, systematic, and focused in-situ exploration of the Earth's lower ionosphere and thermosphere below 200 km that will produce a pivotal base of knowledge that will significantly advance our understanding of knowledge that will significantly advance our understanding of how our near-space environment works. The satellite will carry comprehensive in-situ probes to measure vector electric and magnetic fields, plasma density and temperature, ion velocities, ion and neutral composition and winds, energetic particles including suprathermal electrons, gravity waves, and lightning bursts. The satellite will include a propulsion system and tapered body that will provide over 10,000 excursions to altitudes below 200 km with over 3000 dips to altitudes below 150 km. With this instrument complement, spacecraft, and orbit, the Dipper mission will gather the necessary combined electrodynamics and neutral dynamics measurements to provide an understanding of the Earth's critical boundary region where the ionized gases of space and the neutral gases of the atmosphere are coupled, and where impinging forces and momentum are deposited from the magnetosphere above and from the troposphere, stratosphere, and mesosphere below. In exploring those physical processes in the lower ionosphere which can only be measured in-situ, the Dipper mission addresses four main science objectives. The Dipper will: 1) reveal how ion-neutral coupling creates a global system of dynamo electric fields and currents; 2) provide first-hand understanding of how magnetospheric currents close in the ionosphere and reveal the effects on the upper atmosphere of magnetospheric energy and momentum deposition; 3) discover the degree of upwards coupling and energy deposition due to thunderstorm electric fields and determine their significance; 4) determine the dynamics and composition of the Earth's lower thermosphere, including its response to gravity, tidal, and planetary waves on a range of spatial scales. A proposal to design, build, operate, and analyze data from instruments on the Dipper spacecraft within the schedule and budget constraints of NASA's MIDEX program was submitted to NASA in 1998. This presentation summarizes the main features of the mission.

Published
1999

27. DC and Wave Electric Fields and Other Plasma Parameters Observed on Two Sounding Rockets in the Dark Cusp during IMF BZ North and South Conditions

Author

Pfaff, R. F, Bounds, S, Acuna, M, Maynard, N. C, Moen, J, Egeland, A, Holtet, J, Maseide, K, Sandholt, P. E, and Soraas, F

Subjects
Geophysics
Abstract

Two Black Brant IX sounding rockets were launched into the dark, dayside cusp near magnetic noon on December 2 and 3, 1997, from Ny Alesund, Spitzbergen at 79degN reaching altitudes of approximately 450 km. Real-time ground-based and Wind (interplanetary magnetic field) IMF data were used to determine the launch conditions. The first launch, with Bz north conditions, crossed into and back out of an open field region with merging poleward of the projected trajectory. The second flight, into Bz south conditions, was timed to coincide with an enhancement in the merging rate from a increase in the negative Bz, while the (Defense Meteorological Satellite Program) DMSP F13 satellite was situated slightly to the north of the rocket trajectory. Each payload returned DC electric and magnetic fields, plasma waves, energetic particles, photometer data, and thermal plasma data. Data from both flights will be shown, with an emphasis on the DC electric field results. In particular, the data gathered on December 2, 1997 will be used to discuss ionospheric signatures of merging and the open/closed character of the the cusp/low latitude boundary layer. In contrast, the data gathered on December 3, 1997 shows evidence of pulsed electric field structures which will be examined in the context of cusp plasma entry processes. Both data sets returned a rich variety of plasma waves, as well as optical emissions and thermal plasma data.

Published
1999

28. Rocket/Radar Sporadic-E Experiment Conducted during the El Coqui 2 Campaign

Author

Pfaff, R.F, Acuna, M, Bounds, S, Freudenreich, H, Clemmons, J, Earle, G, Heelis, R, Kudeki, E, Franke, S, and Larsen, M

Subjects
Geophysics
Abstract

In order to investigate the complex electrodynamics and neutral-plasma coupling inherent to sporadic-E layers in the earth's mid-latitude ionosphere, a series of rocket/radar experiments were planned as part of the NASA El Coqui H Campaign from Tortuguero Launch Range, Puerto Rico, in March-April, 1998. The rocket experiments consisted of two pairs of "mother-daughter" payloads with limited apogees so that the payloads "hovered" in the sporadic-E region (95-125 km). Each payload pair included vector DC and AC electric field detectors, a highly accurate flux-gate DC magnetometer, an ion mass spectrometer, an ionization gauge, and spaced-electric field receivers to measure the wavelength and phase velocity of the unstable plasma waves. Separate rockets were included to simultaneously carry aloft TMA trails to measure the neutral wind and its velocity shear, believed responsible for the sporadic-E layer formation. In addition to the rocket experiments, incoherent scatter radar measurements of plasma density and drift velocity were gathered almost every night during the 3 week campaign. Continuous VHF backscatter radar operations were carried out from a site near Salinas, Puerto Rico, where 3-m backscatter echoes were observed associated with sporadic-E and other types of low altitude ionospheric layers. Other radars that operated during the campaign included an HF backscatter system near Ponce, Puerto Rico, and a second VHF backscatter radar set up near Aguadila Puerto Rico. On 24 March 1998, one of the instrumented rockets was launched, attaining an apogee of 129 km. The payloads successfully pierced an intense sporadic-E layer observed by both the Arecibo radar and the in-situ density and ion mass spectrometer probes. In-situ DC electric fields revealed very low (about 1-2 mV/m) ambient fields with small amplitude structures of the same order. No high frequency (short scale) waves were observed, consistent with the VHF backscatter observations at the time of the launch. An overview of the observations will be presented.

Published
1999

29. DC and Wave Electric Fields and Other Plasma Parameters Observed on Two Sounding Rockets in the Dark Cusp During IMF Bz North and South Conditions

Author

Pfaff, R. F, Acuna, M, Bounds, S, Farrell, W, Freudenreich, H, Lepping, R, Vondrak, R, Maynard, N. C, Moen, J, and Egeland, A

Subjects
Geophysics
Abstract

Two Black Brant IX sounding rockets were launched into the dark, dayside cusp near magnetic noon on December 2 and 3, 1997, from Ny Alesund, Spitzbergen at 79 N reaching altitudes of approximately 450 km. Real-time ground-based and Wind IMF data were used to determine the launch conditions. The first launch, with Bz north conditions, crossed into and back out of an open field region with merging poleward of the projected trajectory. The second flight, into Bz south conditions, was timed to coincide with an enhancement in the merging rate from a increase in the negative Bz, while the DMSP F13 satellite was situated slightly to the north of the rocket trajectory. Each payload returned DC electric and magnetic fields, plasma waves, energetic particles, photometer data, and thermal plasma data. Data from both flights will be shown, with an emphasis on the DC electric field results. In particular, the data gathered on December 2, 1997 will be used to discuss ionospheric signatures of merging and the open/closed character of the the cusp/low latitude boundary layer. In contrast, the data gathered on December 3, 1997 shows evidence of pulsed electric field structures which will be examined in the context of cusp plasma entry processes. Both data sets returned a rich variety of plasma waves, as well as optical emissions and thermal plasma data.

Published
1997

30. One person dies in crash on U.S. 36 west of Lyons

Author

Bear, John and Bounds/s, Amy

Subjects
Traffic accidents, News, opinion and commentary, Sports and fitness
Abstract

Byline: John Bear and Amy Bounds/s One person died and two others were injured Saturday night in a two-vehicle crash on U.S. 36 west of Lyons, according to the Colorado [...]

Published
2018

31. Using the cold plasma dispersion relation and whistler mode waves to quantify the antenna sheath impedance of the Van Allen Probes EFW instrument

Author

Hartley, D P, Kletzing, C A, Kurth, W S, Bounds, S R, Averkamp, T F, Hospodarsky, G B, Wygant, J R, Bonnell, J W, Santolik, O, and Watt, Clare E J

Subjects
Physics::Space Physics
Abstract

Cold plasma theory and parallel wave propagation are often assumed when approximating the whistler mode magnetic field wave power from electric field observations. The current study is the first to include the wave normal angle from the Electric and Magnetic Field Instrument Suite and Integrated Science package on board the Van Allen Probes in the conversion factor, thus allowing for the accuracy of these assumptions to be quantified. Results indicate that removing the assumption of parallel propagation does not significantly affect calculated plasmaspheric hiss wave powers. Hence, the assumption of parallel propagation is valid. For chorus waves, inclusion of the wave normal angle in the conversion factor leads to significant alterations in the distribution of wave power ratios (observed/ calculated); the percentage of overestimates decreases, the percentage of underestimates increases, and the spread of values is significantly reduced. Calculated plasmaspheric hiss wave powers are, on average, a good estimate of those observed, whereas calculated chorus wave powers are persistently and systematically underestimated. Investigation of wave power ratios (observed/calculated), as a function of frequency and plasma density, reveals a structure consistent with signal attenuation via the formation of a plasma sheath around the Electric Field and Waves spherical double probes instrument. A simple, density-dependent model is developed in order to quantify this effect of variable impedance between the electric field antenna and the plasma interface. This sheath impedance model is then demonstrated to be successful in significantly improving agreement between calculated and observed power spectra and wave powers.

Published
2016

33. First MMS Observations of High Time Resolution 3D Electric and Magnetic fields at the Dayside Magnetopause

Author

Torbert, R. B., Burch, J. L., Russell, C. T., Magnes, W., Ergun, R. E., Lindqvist, P. A., Le Contel, Olivier, Vaith, H., Macri, J., Myers, S., Rau, D., Needell, J., King, B., Granoff, M., Chutter, M., Dors, I., Argall, M. R., Shuster, J. R., Olsson, G., Marklund, G. T., Khotyaintsev, Y. V., Eriksson, A. I., Kletzing, C., Bounds, S. R., Anderson, B. J., Baumjohann, W., Steller, M., Bromund, K. R., Le, G., Nakamura, R., Strangeway, R. J., Leinweber, H. K., Tucker, S., Westfall, J., Fischer, D., Plaschke, F., Pollock, C. J., Giles, B. L., Moore, T. E., Mauk, B., Fuselier, S. A., Royal Institute of Technology [Stockholm] (KTH ), Laboratoire de Physique des Plasmas (LPP), Université Paris-Saclay-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris-Sud - Paris 11 (UP11)-École polytechnique (X)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL), University of New Hampshire (UNH), Swedish Institute of Space Physics [Uppsala] (IRF), Department of Physics and Astronomy [Iowa City], University of Iowa [Iowa City], Space Research Institute of Austrian Academy of Sciences (IWF), Austrian Academy of Sciences (OeAW), and University of Colorado [Boulder]

Subjects
[PHYS.PHYS.PHYS-PLASM-PH]Physics [physics]/Physics [physics]/Plasma Physics [physics.plasm-ph], Physics::Space Physics, [PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph]
Abstract

International audience; The electrodynamics at the magnetopause is key to our understanding of ion and electron acceleration within reconnection regions. The Magnetospheric Multiscale (MMS) fleet of four spacecraft was launched into its Phase-1 equatorial orbit of 12 Re apogee specifically to investigate these regions at the Earth's magnetopause. In addition to a comprehensive suite of particle measurements, MMS makes very high time resolution 3D electric and magnetic field measurements of high accuracy using flux-gate, search coil, 3-axis double probe, and electron drift sensors. In September 2015, the MMS fleet will begin to encounter the dusk-side magnetopause in its initial configuration of approximately 160 km separation, allowing investigation of the spatial and temporal characteristics of important electrodynamics during reconnection. Using these field and particle measurements, we present first observations of 3D magnetic and electric fields (including their parallel component), and inferred current sheets, during active magnetopause crossings using the highest time resolution data available on MMS.

Published
2015

34. Effect of electron ambient plasmas in reconnection jets and dipolarization fronts : MMS initial results

Author

Nakamura, R., Torkar, K., Andriopoulou, M., Jeszenszky, H., Plaschke, F., Baumjohann, W., Magnes, W., Fischer, D., Schmid, D., Steller, M., Nakamura, T., Scharlemann, C., Torbert, R. B., Burch, J. L., Ergun, R. E., Lindqvist, P. A., Marklund, G. T., Khotyaintsev, Y. V., Russell, C. T., Strangeway, R. J., Leinweber, H. K., Anderson, B. J., Le, G., Bromund, K. R., Fuselier, S. A., Chutter, M., Slavin, J. A., Kepko, L., Le Contel, Olivier, Pollock, C. J., Dorelli, J. C., Gershman, D. J., Mauk, B., Vaith, H., Kletzing, C., Bounds, S. R., Sigsbee, K. M., Space Research Institute of Austrian Academy of Sciences (IWF), Austrian Academy of Sciences (OeAW), Laboratory for Atmospheric and Space Physics [Boulder] (LASP), University of Colorado [Boulder], Alfven Laboratory, Royal Institute of Technology [Stockholm] (KTH ), Swedish Institute of Space Physics [Kiruna] (IRF), NASA Goddard Space Flight Center (GSFC), Laboratoire de Physique des Plasmas (LPP), Université Paris-Saclay-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris-Sud - Paris 11 (UP11)-École polytechnique (X)-Observatoire de Paris, and Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)

Subjects
[PHYS.PHYS.PHYS-PLASM-PH]Physics [physics]/Physics [physics]/Plasma Physics [physics.plasm-ph], Physics::Space Physics, [PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph]
Abstract

International audience; With the successful launch of Magnetospheric Multiscale Misssion (MMS), it becomes possible to observe the dynamic signatures of magnetospheric transients with high-time resolution measurements of electromagnetic fields and plasma. The Active Spacecraft Potential Control (ASPOC) neutralizes the spacecraft potential by releasing positive charge produced by indium and thereby controlling the spacecraft potential in order to enable accurate measurements also in sparse plasma environments essential to study properties of reconnection. Since the current balance around the spacecraft is maintained by contribution also from the ambient plasma, predominantly electrons, ASPOC beam current values combined with spacecraft potential data from FIELDS instruments enable to deduce the ambient electron plasma parameters . Particularly, using data from multi-spacecraft measurements with different ASPOC current levels and FIELDS data, parameters on ambient electron temperature and density can be deduced. Monitoring the environmental plasma parameters are essential to determine the accurate scales of the structure or wave length relative to plasma scales and hence to understand the physical processes. In this study we investigate the changes of the electron parameters in the transient structures such as the magnetic field disturbance forming at the front of BBF/flow bursts, called dipolarization front (DF), and reconnection jets in thin current sheets obtained by MMS mainly during the commissioning phase when the spacecraft traversed the near-Earth tail.

Published
2015

36. Estimates of terms in Ohm's law during an encounter with an electron diffusion region

Author

Torbert, R. B., Burch, J. L., Giles, B. L., Gershman, D., Pollock, C. J., Dorelli, J., Avanov, L., Argall, M. R., Shuster, J., Strangeway, R. J., Russell, C. T., Ergun, R. E., Wilder, F. D., Goodrich, K., Faith, H. A., Farrugia, C. J., Lindqvist, Per-Arne, Phan, T., Khotyaintsev, Y., Moore, T. E., Marklund, Göran, Daughton, W., Magnes, W., Kletzing, C. A., Bounds, S., Torbert, R. B., Burch, J. L., Giles, B. L., Gershman, D., Pollock, C. J., Dorelli, J., Avanov, L., Argall, M. R., Shuster, J., Strangeway, R. J., Russell, C. T., Ergun, R. E., Wilder, F. D., Goodrich, K., Faith, H. A., Farrugia, C. J., Lindqvist, Per-Arne, Phan, T., Khotyaintsev, Y., Moore, T. E., Marklund, Göran, Daughton, W., Magnes, W., Kletzing, C. A., and Bounds, S.

Abstract

We present measurements from the Magnetospheric Multiscale (MMS) mission taken during a reconnection event on the dayside magnetopause which includes a passage through an electron diffusion region (EDR). The four MMS satellites were separated by about 10 km such that estimates of gradients and divergences allow a reasonable estimate of terms in the generalized Ohm's law, which is key to investigating the energy dissipation during reconnection. The strength and character of dissipation mechanisms determines how magnetic energy is released. We show that both electron pressure gradients and electron inertial effects are important, but not the only participants in reconnection near EDRs, since there are residuals of a few mV/m (similar to 30-50%) of E + U-e x B (from the sum of these two terms) during the encounters. These results are compared to a simulation, which exhibits many of the observed features, but where relatively little residual is present., QC 20160926

Published
2016
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37. Estimates of terms in Ohm's law during an encounter with an electron diffusion region

Author

Torbert, R. B., primary, Burch, J. L., additional, Giles, B. L., additional, Gershman, D., additional, Pollock, C. J., additional, Dorelli, J., additional, Avanov, L., additional, Argall, M. R., additional, Shuster, J., additional, Strangeway, R. J., additional, Russell, C. T., additional, Ergun, R. E., additional, Wilder, F. D., additional, Goodrich, K., additional, Faith, H. A., additional, Farrugia, C. J., additional, Lindqvist, P.‐A., additional, Phan, T., additional, Khotyaintsev, Y., additional, Moore, T. E., additional, Marklund, G., additional, Daughton, W., additional, Magnes, W., additional, Kletzing, C. A., additional, and Bounds, S., additional

Published
2016
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41. Plasma Wave Measurements from the Van Allen Probes

Author

Hospodarsky, George B., Kurth, W. S., Kletzing, C. A., Bounds, S. R., Santolik, O., Wygant, J. R., and Bonnell, J. W.

Subjects
Physics::Plasma Physics, Physics::Space Physics
Abstract

The twin Van Allen Probes spacecraft were launched on August 30, 2012 to study the Earth's Van Allen radiation belts. The Electric and Magnetic Field Instrument Suite and Integrated Science (EMFISIS) investigation includes a plasma wave instrument (Waves) that simultaneously measures three orthogonal components of the wave magnetic field from ~10 Hz to 12 kHz and, with the support of the Electric Fields and Waves (EFW) instrument sensors, three components of the wave electric field from ~10 Hz to 12 kHz and a single electric component up to ~400 kHz. Since launch, a variety of plasma waves have been detected which are believed to play a role in the dynamics of the radiation belts, including whistler-mode chorus, plasmaspheric hiss, and magnetosonic equatorial noise. Lightning produced whistlers, electron cyclotron harmonic (ECH) emission, and the upper hybrid resonance (UHR) are also often detected. The UHR is used to determine the local electron plasma density (an important parameter of the plasma required for various modeling and simulation studies). Measuring all six components simultaneously allow the wave propagation parameters of these plasma wave emissions, including the Poynting flux, wave normal vector, and polarization, to be obtained. The Waves instrument is able to determine these parameters with both onboard and ground processing at very high time and frequency resolutions. We will summarize the EMFISIS plasma wave observations and discuss their role in the Van Allen Radiation Belt dynamics.

Published
2014

42. The Electron Drift Instrument for MMS

Author

Torbert, R. B., primary, Vaith, H., additional, Granoff, M., additional, Widholm, M., additional, Gaidos, J. A., additional, Briggs, B. H., additional, Dors, I. G., additional, Chutter, M. W., additional, Macri, J., additional, Argall, M., additional, Bodet, D., additional, Needell, J., additional, Steller, M. B., additional, Baumjohann, W., additional, Nakamura, R., additional, Plaschke, F., additional, Ottacher, H., additional, Hasiba, J., additional, Hofmann, K., additional, Kletzing, C. A., additional, Bounds, S. R., additional, Dvorsky, R. T., additional, Sigsbee, K., additional, and Kooi, V., additional

Published
2015
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43. Van Allen Probes investigation of the large‐scale duskward electric field and its role in ring current formation and plasmasphere erosion in the 1 June 2013 storm

Author

Thaller, S. A., primary, Wygant, J. R., additional, Dai, L., additional, Breneman, A. W., additional, Kersten, K., additional, Cattell, C. A., additional, Bonnell, J. W., additional, Fennell, J. F., additional, Gkioulidou, Matina, additional, Kletzing, C. A., additional, De Pascuale, S., additional, Hospodarsky, G. B., additional, and Bounds, S. R., additional

Published
2015
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45. Current Closure in the Ionosphere: Results from the ACES Sounding Rocket

Author

Kaeppler, S. R., Bounds, S. R., Kletzing, C., Gjerloev, J. W., Anderson, B. J., Korth, H., Labelle, J. W., Dombrowski, M. P., Lessard, M., Jones, S., Pfaff, R. F., Rowland, D. E., Heinselman, C. J., Dudok de Wit, Thierry, and POTHIER, Nathalie

Subjects
2704 MAGNETOSPHERIC PHYSICS / Auroral phenomena, 2721 MAGNETOSPHERIC PHYSICS / Field-aligned currents and current systems, 2794 MAGNETOSPHERIC PHYSICS / Instruments and techniques, [PHYS.ASTR] Physics [physics]/Astrophysics [astro-ph]
Abstract

The Auroral Current and Electrodynamics Structure (ACES) rockets were launched into a substorm auroral arc, from Poker Flat Research Range, AK on January 29, 2009. The ACES rocket mission, in conjunction with the PFISR Radar, was designed to observe directly the three dimensional current system of an auroral arc during quiet-time conditions. ACES utilized two well instrumented payloads flown along very similar magnetic field footprints. The higher altitude payload (apogee 330 km) took in-situ measurements of the plasma parameters above the current closure region to provide the input signature into the lower ionosphere. The low altitude payload (apogee 130 km) took similar observations within the current closure region, where cross-field currents can flow. We present results comparing the electric and magnetic fields, density measurements and electron particle data on the two payloads. We examine these measurements to understand ionospheric conductivity and how energy is being deposited into the ionosphere through Joule heating. We further compare the plasma measurements between the high and low altitude payload to make inferences about current closure geometry.

Published
2010

46. Plasma Wave and Electron Density Structure Observed in the Cusp with a Dual-Rocket Experiment

Author

Colpitts, C. A., Labelle, J. W., Kletzing, C., Bounds, S., Cairns, I., Yeoman, T., Pitout, Frederic, Pibaret-Bourdon, Béatrice, 6127 Wilder Laboratory, Dartmouth College [Hanover], Department of Physics and Astronomy [Iowa City], University of Iowa [Iowa City], School of Physics A28, The University of Sydney, Laboratoire de Planétologie de Grenoble (LPG), and Université Joseph Fourier - Grenoble 1 (UJF)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)

Subjects
Astrophysics::Instrumentation and Methods for Astrophysics
Abstract

SM13A-1659; The Twin Rockets to Investigate Cusp Electrodynamics (TRICE) were launched on December 10, 2007, from Andoya Research Range in Andenes, Norway, into the active cusp. Both payloads traveled north over Svalbard, with one payload reaching an apogee of ~1100 km, and the other reaching ~600 km. The payloads were separated by 100-400 km during the main portion of the flight. Both payloads included waveform receivers with 5 MHz bandwidth. These recorded several distinct types of auroral waves including whistler mode waves below ~1000 kHz and Langmuir-upper hybrid waves at 300-3000 kHz for several hundred km. Both payloads concurrently encountered a distinct period of Langmuir turbulence. Clearly defined wave cutoffs provide measurements of electron density and reveal significant density structure with density enhancements having amplitudes up to 100 percent and scale sizes from meters to tens of kilometers. Analysis of the inferred density profiles using windowed Fourier Transforms or Lomb-Scargle periodograms generates dynamic spectra of the density, which provide estimates of the spectral composition of the density irregularities for time intervals sufficiently short that the stationarity of the spectra can be investigated. The large-scale structures through which the two payloads propagated were measured by both the EISCAT and SuperDARN radars as well as by all-sky cameras operated at Longyearbyen and Ny-Alesund on Svalbard. Using this data when available, comparison of the density irregularity waveforms and spectra from the two flights is studied in relation to spatial and altitude variations of the turbulence. This examination of wave and density structures and the large scale formations with which they are associated will add to the understanding of the large scale electrodynamics of the cusp region.

Published
2008

48. The FIELDS Instrument Suite on MMS: Scientific Objectives, Measurements, and Data Products

Author

Torbert, R. B., primary, Russell, C. T., additional, Magnes, W., additional, Ergun, R. E., additional, Lindqvist, P.-A., additional, LeContel, O., additional, Vaith, H., additional, Macri, J., additional, Myers, S., additional, Rau, D., additional, Needell, J., additional, King, B., additional, Granoff, M., additional, Chutter, M., additional, Dors, I., additional, Olsson, G., additional, Khotyaintsev, Y. V., additional, Eriksson, A., additional, Kletzing, C. A., additional, Bounds, S., additional, Anderson, B., additional, Baumjohann, W., additional, Steller, M., additional, Bromund, K., additional, Le, Guan, additional, Nakamura, R., additional, Strangeway, R. J., additional, Leinweber, H. K., additional, Tucker, S., additional, Westfall, J., additional, Fischer, D., additional, Plaschke, F., additional, Porter, J., additional, and Lappalainen, K., additional

Published
2014
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50. Auroral Current and Electrodynamics Structure (ACES) observations of ionospheric feedback in the Alfvén resonator and model responses

Author

Cohen, I. J., primary, Lessard, M. R., additional, Kaeppler, S. R., additional, Bounds, S. R., additional, Kletzing, C. A., additional, Streltsov, A. V., additional, LaBelle, J. W., additional, Dombrowski, M. P., additional, Jones, S. L., additional, Pfaff, R. F., additional, Rowland, D. E., additional, Anderson, B. J., additional, Korth, H., additional, and Gjerloev, J. W., additional

Published
2013
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