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1. Parker Solar Probe evidence for the absence of whistlers close to the Sun to scatter strahl and regulate heat flux

Author

Cattell, C., Breneman, A., Dombeck, J., Hanson, E., Johnson, M., Halekas, J., Bale, S. D., de Wit, T. Dudok, Goetz, K., Goodrich, K., Malaspina, D., Pulupa, M., Case, T., Kasper, J. C., Larson, D., Stevens, M., and Whittlesey, P.

Subjects
Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics, Physics - Space Physics
Abstract

Using the Parker Solar Probe FIELDS bandpass filter data and SWEAP electron data from Encounters 1 through 9, we show statistical properties of narrowband whistlers from ~16 Rs to ~130 Rs, and compare wave occurrence to electron properties including beta, temperature anisotropy and heat flux. Whistlers are very rarely observed inside ~28 Rs (~0.13 au). Outside 28 Rs, they occur within a narrow range of parallel electron beta from ~1 to 10, and with a beta-heat flux occurrence consistent with the whistler heat flux fan instability. Because electron distributions inside ~30 Rs display signatures of the ambipolar electric field, the lack of whistlers suggests that the modification of the electron distribution function associated with the ambipolar electric field or changes in other plasma properties must result in lower instability limits for the other modes (including solitary waves, ion acoustic waves) that are observed close to the Sun. The lack of narrowband whistler-mode waves close to the Sun and in regions of either low (<.1) or high (>10) beta is also significant for the understanding and modeling of the evolution of flare-accelerated electrons, and the regulation of heat flux in astrophysical settings including other stellar winds, the interstellar medium, accretion disks, and the intra-galaxy cluster medium

Published
2021
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2. Direct Multipoint Observations Capturing the Reformation of a Supercritical Fast Magnetosonic Shock

Author

Turner, D. L., Wilson III, L. B., Goodrich, K. A., Madanian, H., Schwartz, S. J., Liu, T. Z., Johlander, A., Caprioli, D., Cohen, I. J., Gershman, D., Hietala, H., Westlake, J. H., Lavraud, B., Contel, O. Le, and Burch, J. L.

Subjects
Physics - Space Physics, Astrophysics - Earth and Planetary Astrophysics, Astrophysics - High Energy Astrophysical Phenomena, Astrophysics - Solar and Stellar Astrophysics
Abstract

Using multipoint Magnetospheric Multiscale (MMS) observations in an unusual string-of-pearls configuration, we examine in detail observations of the reformation of a fast magnetosonic shock observed on the upstream edge of a foreshock transient structure upstream of Earth's bow shock. The four MMS spacecraft were separated by several hundred km, comparable to suprathermal ion gyro-radius scales or several ion inertial lengths. At least half of the shock reformation cycle was observed, with a new shock ramp rising up out of the "foot" region of the original shock ramp. Using the multipoint observations, we convert the observed time-series data into distance along the shock normal in the shock's rest frame. That conversion allows for a unique study of the relative spatial scales of the shock's various features, including the shock's growth rate, and how they evolve during the reformation cycle. Analysis indicates that: the growth rate increases during reformation, electron-scale physics play an important role in the shock reformation, and energy conversion processes also undergo the same cyclical periodicity as reformation. Strong, thin electron-kinetic-scale current sheets and large-amplitude electrostatic and electromagnetic waves are reported. Results highlight the critical cross-scale coupling between electron-kinetic- and ion-kinetic-scale processes and details of the nature of nonstationarity, shock-front reformation at collisionless, fast magnetosonic shocks., Comment: In press and to be published in Astrophysical Journal Letters in 2021

Published
2021
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3. Parker Solar Probe evidence for scattering of electrons in the young solar wind by narrowband whistler-mode waves

Author

Cattell, C., Breneman, A., Dombeck, J., Short, B., Wygant, J., Halekas, J., Case, Tony, Kasper, J., Larson, D., Stevens, Mike, Whittesley, P., de Wit, S. Bale T. Dudok, Goodrich, K., MacDowall, R., Moncuquet, M., Malaspina, D., and Pulupa, M.

Subjects
Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics
Abstract

Observations of plasma waves by the Fields Suite and of electrons by the Solar Wind Electrons Alphas and Protons Investigation (SWEAP) on Parker Solar Probe provide strong evidence for pitch angle scattering of strahl-energy electrons by narrowband whistler-mode waves at radial distances less than ~0.3 AU. We present two example intervals of a few hours that include 8 waveform captures with whistler-mode waves and 26 representative electron distributions that are examined in detail. Two were narrow; 17 were clearly broadened, and 8 were very broad. The two with narrow strahl occurred when there were either no whistlers or very intermittent low amplitude waves. Six of the eight broadest distributions were associated with intense, long duration waves. Approximately half of the observed electron distributions have features consistent with an energy dependent scattering mechanism, as would be expected from interactions with narrowband waves. A comparison of the wave power in the whistler-mode frequency band to pitch angle width and a measure of anisotropy provides additional evidence for the electron scattering by whistler-mode waves. The pitch angle broadening occurs in over an energy range comparable to that obtained for the n=1 (co-streaming) resonance for the observed wave and plasma parameters. The additional observation that the heat flux is lower in the interval with multiple switchbacks may provide clues to the nature of switchbacks. These results provide strong evidence that the heat flux is reduced by narroweband whistler-mode waves scattering of strahl-energy electrons., Comment: 19 pages, 4 figures, 1 table

Published
2021
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4. Narrowband oblique whistler-mode waves: Comparing properties observed by Parker Solar Probe at <0.2 AU and STEREO at 1 AU

Author

Cattell, C., Short, B., Breneman, A., Halekas, J., Whittesley, P., Kasper, J., Stevens, Mike, Case, Tony, Moncuquet, M., Bale, S., Bonnell, J., de Wit, T. Dudok, Goetz, K., Harvey, P., MacDowall, R., Malaspina, D., Pulupa, M., and Goodrich, K.

Subjects
Physics - Space Physics, Physics - Plasma Physics
Abstract

AIM: Large amplitude narrowband obliquely propagating whistler-mode waves at frequencies of ~0.2 fce (electron cyclotron frequency) are commonly observed at 1 AU, and are most consistent with the whistler heat flux fan instability. We want to determine whether similar whistler-mode waves occur inside 0.2 AU, and how their properties compare to those at 1 AU. METHODS: We utilize the waveform capture data from the Parker Solar Probe Fields instrument to develop a data base of narrowband whistler waves. The SWEAP instrument, in conjunction with the quasi-thermal noise measurement form Fields, provides the electron heat flux, beta, and other electron parameters. RESULTS: Parker Solar Probe observations inside ~0.3 AU show that the waves are more intermittent than at 1 AU, and are often interspersed with electrostatic whistler/Bernstein waves at higher frequencies. This is likely due to the more variable solar wind observed closer to the Sun. The whistlers usually occur within regions when the magnetic field is more variable and often with small increases in the solar wind speed. The near-sun whistler-mode waves are also narrowband and large amplitude, and associated with beta greater than 1. Wave angles are sometimes highly oblique (near the resonance cone), but angles have been determined for only a small fraction of the events. The association with heat flux and beta is generally consistent with the whistler fan instability although there are intervals where the heat flux is significantly lower than the instability limit. Strong scattering of strahl energy electrons is seen in association with the waves, providing evidence that the waves regulate the electron heat flux..

Published
2020
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5. Localized magnetic field structures and their boundaries in the near-Sun solar wind from Parker Solar Probe measurements

Author

Krasnoselskikh, V., Larosa, A., Agapitov, O., de Wit, T. Dudok, Moncuquet, M., Mozer, F. S., Stevens, M., Bale, S. D., Bonnell, J., Froment, C., Goetz, K., Goodrich, K., Harvey, P., Kasper, J., MacDowall, R., Malaspina, D., Pulupa, M., Raouafi, N., Revillet, C., Velli, M., and Wygant, J.

Subjects
Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics
Abstract

One of the discoveries made by Parker Solar Probe during first encounters with the Sun is the ubiquitous presence of relatively small-scale structures standing out as sudden deflections of the magnetic field. They were called switchbacks as some of them show up the full reversal of the radial component of the magnetic field and then return to regular conditions. Analyzing the magnetic field and plasma perturbations associated with switchbacks we identify three types of structures with slightly different characteristics: 1. Alfvenic structures, where the variations of the magnetic field components take place while the magnitude of the field remains constant; 2. Compressional, the field magnitude varies together with changes of the components; 3. Structures manifesting full reversal of the magnetic field (extremal class of Alfvenic structures). Processing of structures boundaries and plasma bulk velocity perturbations lead to the conclusion that they represent localized magnetic field tubes with enhanced parallel plasma velocity and ion beta moving together with respect to surrounding plasma. The magnetic field deflections before and after the switchbacks reveal the existence of total axial current. The electric currents are concentrated on the relatively narrow boundary layers on the surface of the tubes and determine the magnetic field perturbations inside the tube. These currents are closed on the structure surface, and typically have comparable azimuthal and the axial components. The surface of the structure may also accommodate an electromagnetic wave, that assists to particles in carrying currents. We suggest that the two types of structures we analyzed here may represent the local manifestations of the tube deformations corresponding to a saturated stage of the Firehose instability development., Comment: 27 pages, 18 Figures, submitted to ApJ Supplement

Published
2020
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6. Sunward propagating whistler waves collocated with localized magnetic field holes in the solar wind: Parker Solar Probe observations at 35.7 Sun radii

Author

Agapitov, O. V., de Wit, T. Dudok, Mozer, F. S., Bonnell, J. W., Drake, J. F., Malaspina, D., Krasnoselskikh, V., Bale, S., Whittlesey, P. L., Case, A. W., Chaston, C., Froment, C., Goetz, K., Goodrich, K. A., Harvey, P. R., Kasper, J. C., Korreck, K. E., Larson, D. E., Livi, R., MacDowall, R. J., Pulupa, M., Revillet, C., Stevens, M., and Wygant, J. R.

Subjects
Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics
Abstract

Observations by the Parker Solar Probe mission of the solar wind at about 35.7 solar radii reveal the existence of whistler wave packets with frequencies below 0.1 f/fce (20-80 Hz in the spacecraft frame). These waves often coincide with local minima of the magnetic field magnitude or with sudden deflections of the magnetic field that are called switchbacks. Their sunward propagation leads to a significant Doppler frequency downshift from 200-300 Hz to 20-80 Hz (from 0.2 f/fce to 0.5 f/fce). The polarization of these waves varies from quasi-parallel to significantly oblique with wave normal angles that are close to the resonance cone. Their peak amplitude can be as large as 2 to 4 nT. Such values represent approximately 10% of the background magnetic field, which is considerably more than what is observed at 1 a.u. Recent numerical studies show that such waves may potentially play a key role in breaking the heat flux and scattering the Strahl population of suprathermal electrons into a halo population.

Published
2020
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7. Time domain structures and dust in the solar vicinity: Parker Solar Probe observations

Author

Mozer, F. S., Agapitov, O. V., Bale, S. D., Bonnell, J. W., Goetz, K., Goodrich, K. A., Gore, R., Harvey, P. R., Kellogg, P. J., Malaspina, D., Pulupa, M., and Schumm, G.

Subjects
Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics
Abstract

On April 5, 2019, while the Parker Solar Probe was at its 35 solar radius perihelion, the data set collected at 293 samples/sec contained more than 10,000 examples of spiky electric-field-like structures having durations less than 200 milliseconds and amplitudes greater than 10 mV/m. The vast majority of these events was caused by plasma turbulence. Defining dust events as those having similar, narrowly peaked, positive, single-ended signatures, resulted in finding 135 clear dust events, which, after correcting for the low detection efficiently, resulted in an estimate consistent with the 1000 dust events expected from other techniques. Defining time domain structures (TDS) as those having opposite polarity signals in the opposite antennas resulted in finding 238 clear TDS events which, after correcting for the detection efficiency, resulted in an estimated 500-1000 TDS events on this day. The TDS electric fields were bipolar, as expected for electron holes. Several events were found at times when the magnetic field was in the plane of the two measured components of the electric field such that the component of the electric field parallel to the magnetic field was measured. One example of significant parallel electric fields shows the negative potential that classified them as electron holes. Because the TDS observation rate was not uniform with time, it is likely that there were local regions below the spacecraft with field-aligned currents that generated the TDS., Comment: First results from the Parker Solar Probe

Published
2019
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8. The Near-Sun Dust Environment: Initial Observations from Parker Solar Probe

Author

Szalay, J. R., Pokorný, P., Bale, S. D., Christian, E. R., Goetz, K., Goodrich, K., Hill, M. E., Kuchner, M., Larsen, R., Malaspina, D., McComas, D. J., Mitchell, D., Page, B., and Schwadron, N.

Subjects
Physics - Space Physics, Astrophysics - Earth and Planetary Astrophysics
Abstract

The Parker Solar Probe (PSP) spacecraft has flown into the most dense and previously unexplored region of our solar system's zodiacal cloud. While PSP does not have a dedicated dust detector, multiple instruments onboard are sensitive to the effects of meteoroid bombardment. Here, we discuss measurements taken during PSP's first two orbits and compare them to models of the zodiacal cloud's dust distribution. Comparing the radial impact rate trends and the timing and location of a dust impact to an energetic particle detector, we find the impactor population to be consistent with dust grains on hyperbolic orbits escaping the solar system. Assuming PSP's impact environment is dominated by hyperbolic impactors, the total quantity of dust ejected from our solar system is estimated to be 1-14 tons/s. We expect PSP will encounter an increasingly more intense impactor environment as its perihelion distance and semi-major axis are decreased., Comment: 34 pages, 10 figures, 3 tables

Published
2019
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9. Plasma Double Layers at the Boundary Between Venus and the Solar Wind

Author

Malaspina, DM, Goodrich, K, Livi, R, Halekas, J, McManus, M, Curry, S, Bale, SD, Bonnell, JW, Wit, T Dudok, Goetz, K, Harvey, PR, MacDowall, RJ, Pulupa, M, Case, AW, Kasper, JC, Korreck, KE, Larson, D, Stevens, ML, and Whittlesey, P

Subjects
kinetic physics, Venus, bow shock, magnetosheath, double layer, solar wind interaction, Meteorology & Atmospheric Sciences
Abstract

The solar wind is slowed, deflected, and heated as it encounters Venus's induced magnetosphere. The importance of kinetic plasma processes to these interactions has not been examined in detail, due to a lack of constraining observations. In this study, kinetic-scale electric field structures are identified in the Venusian magnetosheath, including plasma double layers. The double layers may be driven by currents or mixing of inhomogeneous plasmas near the edge of the magnetosheath. Estimated double-layer spatial scales are consistent with those reported at Earth. Estimated potential drops are similar to electron temperature gradients across the bow shock. Many double layers are found in few high cadence data captures, suggesting that their amplitudes are high relative to other magnetosheath plasma waves. These are the first direct observations of plasma double layers beyond near-Earth space, supporting the idea that kinetic plasma processes are active in many space plasma environments.

Published
2020

10. Localized magnetic-field structures and their boundaries in the near-sun solar wind from parker solar probe measurements

Author

Krasnoselskikh, V, Larosa, A, Agapitov, O, De Wit, TD, Moncuquet, M, Mozer, FS, Stevens, M, Bale, SD, Bonnell, J, Froment, C, Goetz, K, Goodrich, K, Harvey, P, Kasper, J, Macdowall, R, Malaspina, D, Pulupa, M, Raouafi, N, Revillet, C, Velli, M, and Wygant, J

Subjects
Alfven waves, physics.space-ph, astro-ph.SR, Astronomy & Astrophysics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural)
Abstract

One of the discoveries of the Parker Solar Probe during its first encounters with the Sun is ubiquitous presence of relatively small-scale structures standing out as sudden deflections of the magnetic field. They were named "switchbacks" since some of them show a full reversal of the radial component of the magnetic field and then return to "regular" conditions. We carried out an analysis of three typical switchback structures having different characteristics: I. Alfvénic structure, where the variations of the magnetic field components take place while conserving the magnitude of the magnetic field; II. Compressional structure, where the magnitude of the field varies together with changes of its components; and III. Structure manifesting full reversal of the magnetic field, presumably Alfvén, which is an extremal example of a switchback. We analyzed the properties of the magnetic fields of these structures and of their boundaries. Observations and analyses lead to the conclusion that they represent localized twisted magnetic tubes moving with respect to surrounding plasma. An important feature is the existence of a relatively narrow boundary layer at the surface of the tube that accommodates flowing currents. These currents are closed on the surface of the structure and typically have comparable azimuthal and tube-axis-aligned components. They are supported by the presence of an effective electric field due to strong gradients of the density and ion plasma pressure. The ion beta is typically larger inside the structure than outside. The surface of the structure may also accommodate electromagnetic waves that assist particles in carrying currents.

Published
2020

11. Magnetospheric Multiscale Dayside Reconnection Electron Diffusion Region Events

Author

Webster, J. M., Burch, J. L., Reiff, P. H., Graham, D. B., Torbert, R. B., Ergun, R. E., Daou, A. G., Sazykin, S. Y., Marshall, A., Allen, R. C., Chen, L. -J., Wang, S., Phan, T. D., Genestreti, K. J., Giles, B. L., Moore, T. E., Fuselier, S. A., Cozzani, G., Russell, C. T., Eriksson, S., Rager, A. C., Broll, J. M., Goodrich, K., and Wilder, F.

Subjects
Physics - Space Physics
Abstract

We have used the high-resolution data of the Magnetospheric Multiscale (MMS) mission dayside phase to identify twenty-one previously unreported encounters with the electron diffusion region (EDR), as evidenced by electron agyrotropy, ion jet reversals, and j dot E greater than 0. Three of the new EDR encounters, which occurred within a one-minute-long interval on November 23rd, 2016, are analyzed in detail. These events, which resulted from a relatively low and oscillating magnetopause velocity, contained large electric fields (several tens to hundreds of milliVolts per meter), crescent-shaped electron velocity phase space densities, large currents (greater than 2 microAmperes per square meter), and Ohmic heating of the plasma (near or exceeding 10 nanoWatts per cubic meter). Because of the slow in-and-out motion of the magnetopause, two of these events show the unprecedented mixture of perpendicular and parallel crescents, indicating the first breaking and reconnecting of solar wind and magnetospheric field lines. An extended list of thirty-two EDR or near-EDR events is also included, and demonstrates a wide variety of observed plasma behavior inside and surrounding the reconnection site.

Published
2017
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12. Magnetospheric Multiscale Observations of Electron Vortex Magnetic Hole in the Magnetosheath Turbulent Plasma

Author

Huang, S. Y., Sahraoui, F., Yuan, Z. G., He, J. S., Zhao, J. S., Contel, O. Le, Deng, X. H., Zhou, M., Fu, H. S., Pang, Y., Shi, Q. Q., Lavraud, B., Yang, J., Wang, D. D., Yu, X. D., Pollock, C. J., Giles, B. L., Torbert, R. B., Russell, C. T., Goodrich, K. A., Gershman, D. J., Moore, T. E., Ergun, R. E., Khotyaintsev, Y. V., Lindqvist, P. -A., Strangeway, R. J., Magnes, W., Bromund, K., Leinweber, H., Plaschke, F., Anderson, B. J., and Burch, J. L.

Subjects
Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics
Abstract

We report the observations of an electron vortex magnetic hole corresponding to a new type of coherent structures in the magnetosheath turbulent plasma using the Magnetospheric Multiscale (MMS) mission data. The magnetic hole is characterized by a magnetic depression, a density peak, a total electron temperature increase (with a parallel temperature decrease but a perpendicular temperature increase), and strong currents carried by the electrons. The current has a dip in the center of the magnetic hole and a peak in the outer region of the magnetic hole. The estimated size of the magnetic hole is about 0.23 \r{ho}i (~ 30 \r{ho}e) in the circular cross-section perpendicular to its axis, where \r{ho}i and \r{ho}e are respectively the proton and electron gyroradius. There are no clear enhancement seen in high energy electron fluxes, but an enhancement in the perpendicular electron fluxes at ~ 90{\deg} pitch angles inside the magnetic hole is seen, implying that the electron are trapped within it. The variations of the electron velocity components Vem and Ven suggest that an electron vortex is formed by trapping electrons inside the magnetic hole in the circular cross-section (in the M-N plane). These observations demonstrate the existence of a new type of coherent structures behaving as an electron vortex magnetic hole in turbulent space plasmas as predicted by recent kinetic simulations., Comment: 19 pages, 4 figures

Published
2016
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13. Communicating flood risk: Looking back and forward at traditional and social media outlets

Author

Feldman, D, Contreras, S, Karlin, B, Basolo, V, Matthew, R, Sanders, B, Houston, D, Cheung, W, Goodrich, K, Reyes, A, Serrano, K, Schubert, J, and Luke, A

Subjects
Floods, Risk communication, Risk information, Social media, Basic Behavioral and Social Science, Aging, Behavioral and Social Science, Environmental Science and Management, Public Health and Health Services, Human Geography
Abstract

The communication of information about natural hazard risks to the public is a difficult task for decision makers. Research suggests that newer forms of technology present useful options for building disaster resilience. However, how effectively these newer forms of media can be used to inform populations of the potential hazard risks in their community remains unclear. This research uses primary data from an in-person survey of 164 residents of Newport Beach, California during the spring of 2014 to ascertain the current and preferred mechanisms through which individuals receive information on flood risks in their community. Factor analysis of survey data identified two predominant routes of dissemination for risk information: older traditional media and newer social media sources. A logistic regression model was specified to identify predictors for choosing a particular communication route. This analysis revealed that age is the central factor in predicting the sources people use to receive risk information. We follow the analysis by discussing this finding and its policy implications.

Published
2016

14. Highly structured slow solar wind emerging from an equatorial coronal hole

Author

Bale, S. D., Badman, S. T., Bonnell, J. W., Bowen, T. A., Burgess, D., Case, A. W., Cattell, C. A., Chandran, B. D. G., Chaston, C. C., Chen, C. H. K., Drake, J. F., de Wit, T. Dudok, Eastwood, J. P., Ergun, R. E., Farrell, W. M., Fong, C., Goetz, K., Goldstein, M., Goodrich, K. A., Harvey, P. R., Horbury, T. S., Howes, G. G., Kasper, J. C., Kellogg, P. J., Klimchuk, J. A., Korreck, K. E., Krasnoselskikh, V. V., Krucker, S., Laker, R., Larson, D. E., MacDowall, R. J., Maksimovic, M., Malaspina, D. M., Martinez-Oliveros, J., McComas, D. J., Meyer-Vernet, N., Moncuquet, M., Mozer, F. S., Phan, T. D., Pulupa, M., Raouafi, N. E., Salem, C., Stansby, D., Stevens, M., Szabo, A., Velli, M., Woolley, T., and Wygant, J. R.

Published
2019
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16. A research agenda for the science of actionable knowledge: Drawing from a review of the most misguided to the most enlightened claims in the science-policy interface literature

Author

Jagannathan, K, Jagannathan, K, Emmanuel, G, Arnott, J, Mach, KJ, Bamzai-Dodson, A, Goodrich, K, Meyer, R, Neff, M, Sjostrom, KD, Timm, KMF, Turnhout, E, Wong-Parodi, G, Bednarek, AT, Meadow, A, Dewulf, A, Kirchhoff, CJ, Moss, RH, Nichols, L, Oldach, E, Lemos, MC, Klenk, N, Jagannathan, K, Jagannathan, K, Emmanuel, G, Arnott, J, Mach, KJ, Bamzai-Dodson, A, Goodrich, K, Meyer, R, Neff, M, Sjostrom, KD, Timm, KMF, Turnhout, E, Wong-Parodi, G, Bednarek, AT, Meadow, A, Dewulf, A, Kirchhoff, CJ, Moss, RH, Nichols, L, Oldach, E, Lemos, MC, and Klenk, N

Abstract

Linking science with action affords a prime opportunity to leverage greater societal impact from research and increase the use of evidence in decision-making. Success in these areas depends critically upon processes of producing and mobilizing knowledge, as well as supporting and making decisions. For decades, scholars have idealized and described these social processes in different ways, resulting in numerous assumptions that now variously guide engagements at the interface of science and society. We systematically catalog these assumptions based on prior research on the science-policy interface, and further distill them into a set of 26 claims. We then elicit expert perspectives (n = 16) about these claims to assess the extent to which they are accurate or merit further examination. Out of this process, we construct a research agenda to motivate future scientific research on actionable knowledge, prioritizing areas that experts identified as critical gaps in understanding of the science-society interface. The resulting agenda focuses on how to define success, support intermediaries, build trust, and evaluate the importance of consensus and its alternatives – all in the diverse contexts of science-society-decision-making interactions. We further raise questions about the centrality of knowledge in these interactions, discussing how a governance lens might be generative of efforts to support more equitable processes and outcomes. We offer these suggestions with hopes of furthering the science of actionable knowledge as a transdisciplinary area of inquiry.

Published
2023

17. Electron-scale measurements of magnetic reconnection in space

Author

Burch, J. L., Torbert, R. B., Phan, T. D., Chen, L.-J., Moore, T. E., Ergun, R. E., Eastwood, J. P., Gershman, D. J., Cassak, P. A., Argall, M. R., Wang, S., Hesse, M., Pollock, C. J., Giles, B. L., Nakamura, R., Mauk, B. H., Fuselier, S. A., Russell, C. T., Strangeway, R. J., Drake, J. F., Shay, M. A., Khotyaintsev, Yu. V., Lindqvist, P.-A., Marklund, G., Wilder, F. D., Young, D. T., Torkar, K., Goldstein, J., Dorelli, J. C., Avanov, L. A., Oka, M., Baker, D. N., Jaynes, A. N., Goodrich, K. A., Cohen, I. J., Turner, D. L., Fennell, J. F., Blake, J. B., Clemmons, J., Goldman, M., Newman, D., Petrinec, S. M., Trattner, K. J., Lavraud, B., Reiff, P. H., Baumjohann, W., Magnes, W., Steller, M., Lewis, W., Saito, Y., Coffey, V., and Chandler, M.

Published
2016

18. The Axial Double Probe and Fields Signal Processing for the MMS Mission

Author

Ergun, R. E., primary, Tucker, S., additional, Westfall, J., additional, Goodrich, K. A., additional, Malaspina, D. M., additional, Summers, D., additional, Wallace, J., additional, Karlsson, M., additional, Mack, J., additional, Brennan, N., additional, Pyke, B., additional, Withnell, P., additional, Torbert, R., additional, Macri, J., additional, Rau, D., additional, Dors, I., additional, Needell, J., additional, Lindqvist, P.-A., additional, Olsson, G., additional, and Cully, C. M., additional

Published
2016
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19. Generation of Electron Whistler Waves at the Mirror Mode Magnetic Holes: MMS Observations and PIC Simulation

Author

Ahmadi, N, Wilder, F. D, Ergun, R. E, Argall, M, Usanova, M. E, Breuillard, H, Malaspina, D, Paulson, K, Germaschewski, K, Eriksson, S, Goodrich, K, Torbert, R, Contel, O. Le, Strangeway, R. J, Russell, C. T, Burch, J, and Giles, B

Subjects
Geophysics
Abstract

The Magnetospheric Multiscale mission has observed electron whistler waves at the center and at the edges of magnetic holes in the dayside magnetosheath. The magnetic holes are nonlinear mirror structures since their magnitude is anticorrelated with particle density. In this article, we examine the growth mechanisms of these whistler waves and their interaction with the host magnetic hole. In the observations, as magnetic holes develop and get deeper, an electron population gets trapped and develops a temperature anisotropy favorable for whistler waves to be generated. In addition, the decrease in magnetic field magnitude and the increase in density reduce the electron resonance energy, which promotes the electron cyclotron resonance. To investigate this process, we used expanding box particle-in-cell simulations to produce the mirror instability, which then evolve into magnetic holes. The simulation shows that whistler waves can be generated at the center and edges of magnetic holes, which reproduces the primary features of the MMS observations. The simulation shows that the electron temperature anisotropy develops in the center of the magnetic hole once the mirror instability reaches its nonlinear stage of evolution. The plasma is then unstable to whistler waves at the minimum of the magnetic field structures. In the saturation regime of mirror instability, when magnetic holes are developed, the electron temperature anisotropy appears at the edges of the holes and electron distributions become more isotropic at the magnetic field minimum. At the edges, the expansion of magnetic holes decelerates the electrons, which leads to temperature anisotropies.

Published
2018
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20. The Role of the Parallel Electric Field in Electron-Scale Dissipation at Reconnecting Currents in the Magnetosheath

Author

Wilder, F. D, Ergun, R. E, Burch, J. L, Ahmadi, N, Eriksson, S, Phan, T. D, Goodrich, K. A, Shuster, J, Rager, A. C, Torbert, R. B, Giles, B. L, Strangeway, R. J, Plaschke, F, Magnes, W, Lindqvist, P. A, and Khotyaintsev, Y. V

Subjects
Plasma Physics
Abstract

We report observations from the Magnetospheric Multiscale satellites of reconnecting current sheets in the magnetosheath over a range of outofplane "guide" magnetic field strengths. The currents exhibit nonideal energy conversion in the electron frame of reference, and the events are within the ion diffusion region within close proximity (a few electron skin depths) to the electron diffusion region. The study focuses on energy conversion on the electron scale only. At low guide field (antiparallel reconnection), electric fields and currents perpendicular to the magnetic field dominate the energy conversion. Additionally, electron distributions exhibit significant nongyrotropy. As the guide field increases, the electric field parallel to the background magnetic field becomes increasingly strong, and the electron nongyrotropy becomes less apparent. We find that even with a guide field less than half the reconnecting field, the parallel electric field and currents dominate the dissipation. This suggests that parallel electric fields are more important to energy conversion in reconnection than previously thought and that at high guide field, the physics governing magnetic reconnection are significantly different from antiparallel reconnection.

Published
2018
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21. Electron Bulk Acceleration and Thermalization at Earth's Quasiperpendicular Bow Shock

Author

Chen, L.-J, Wang, S, Wilson, L. B., III, Schwartz, S, Bessho, Naoki, Moore, T, Gershman, D, Giles, B, Wilder, F. D, Ergun, R. E, Hesse, M, Lai, H, Russell, C, Strangeway, R, Torbert, R. B, F.-Vinas, A, Burch, J, Lee, S, Pollock, C, Dorelli, J, Paterson, W, Ahmadi, N, Goodrich, K, Lavraud, B, Le Contel, O, Khotyaintsev, Yu V, Lindqvist, P.-A, Boardsen, S, Wei, h, Le, A, and Avanov, L

Subjects
Solar Physics
Abstract

Electron heating at Earth's quasiperpendicular bow shock has been surmised to be due to the combined effects of a quasistatic electric potential and scattering through wave-particle interaction. Here we report the observation of electron distribution functions indicating a new electron heating process occurring at the leading edge of the shock front. Incident solar wind electrons are accelerated parallel to the magnetic field toward downstream, reaching an electron-ion relative drift speed exceeding the electron thermal speed. The bulk acceleration is associated with an electric field pulse embedded in a whistler-mode wave. The high electron-ion relative drift is relaxed primarily through a nonlinear current-driven instability. The relaxed distributions contain a beam traveling toward the shock as a remnant of the accelerated electrons. Similar distribution functions prevail throughout the shock transition layer, suggesting that the observedacceleration and thermalization is essential to the cross-shock electron heating.

Published
2018
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23. Electron Heating at Kinetic Scales in Magnetosheath Turbulence

Author

Chasapis, Alexandros, Matthaeus, W. H, Parashar, T. N, Lecontel, O, Retino, A, Breuillard, H, Khotyaintsev, Y, Vaivads, A, Lavraud, B, Eriksson, E, Moore, T. E, Burch, J. L, Torbert, R. B, Lindqvist, P.-A, Ergun, R. E, Marklund, G, Goodrich, K. A, Wilder, F. D, Chutter, M, Needell, J, Rau, D, Dors, I, Russell, C. T, Le, G, Magnes, W, Strangeway, R. J, Bromund, K. R, Leinweber, H. K, Plaschke, F, Fischer, D, Anderson, B. J, Pollock, C. J, Giles, B. L, Paterson, W. R, Dorelli, J, Gershman, D. J, Avanov, L, and Saito, Y

Subjects
Statistics And Probability, Astrophysics
Abstract

We present a statistical study of coherent structures at kinetic scales, using data from the Magnetospheric Multiscale mission in the Earths magnetosheath. We implemented the multi-spacecraft partial variance of increments (PVI) technique to detect these structures, which are associated with intermittency at kinetic scales. We examine the properties of the electron heating occurring within such structures. We find that, statistically, structures with a high PVI index are regions of significant electron heating. We also focus on one such structure, a current sheet, which shows some signatures consistent with magnetic reconnection. Strong parallel electron heating coincides with whistler emissions at the edges of the current sheet.

Published
2017
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26. Parker Solar Probe Evidence for the Absence of Whistlers Close to the Sun to Scatter Strahl and to Regulate Heat Flux

Author

Cattell, C., primary, Breneman, A., additional, Dombeck, J., additional, Hanson, E., additional, Johnson, M., additional, Halekas, J., additional, Bale, S. D., additional, Dudok de Wit, T., additional, Goetz, K., additional, Goodrich, K., additional, Malaspina, D., additional, Pulupa, M., additional, Case, T., additional, Kasper, J. C., additional, Larson, D., additional, Stevens, M., additional, and Whittlesey, P., additional

Published
2022
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27. Observations of Turbulence in a Kelvin-Helmholtz Event on 8 September 2015 by the Magnetospheric Multiscale Mission

Author

Stawarz, J. E, Eriksson, S, Wilder, F. D, Ergun, R. E, Schwartz, S. J, Pouquet, A, Burch, J. L, Giles, B. L, Khotyaintsev, Y, Le Contel, O, Lindqvist, P.-A, Magnes, W, Pollock, C. J, Russell, C.T, Strangeway, R. J, Torbert, R. B, Avanov, L. A, Dorelli, J. C, Eastwood, J. P, Gershman, D. J, Goodrich, K. A, Malaspina, D. M, Marklund, G. T, Mirioni, L, and Sturner, A. P

Subjects
Solar Physics, Plasma Physics
Abstract

Spatial and high-time-resolution properties of the velocities, magnetic field, and 3-D electric field within plasma turbulence are examined observationally using data from the Magnetospheric Multiscale mission. Observations from a Kelvin-Helmholtz instability (KHI) on the Earth's magnetopause are examined, which both provides a series of repeatable intervals to analyze, giving better statistics, and provides a first look at the properties of turbulence in the KHI. For the first time direct observations of both the high-frequency ion and electron velocity spectra are examined, showing differing ion and electron behavior at kinetic scales. Temporal spectra exhibit power law behavior with changes in slope near the ion gyrofrequency and lower hybrid frequency. The work provides the first observational evidence for turbulent intermittency and anisotropy consistent with quasi two-dimensional turbulence in association with the KHI. The behavior of kinetic-scale intermittency is found to have differences from previous studies of solar wind turbulence, leading to novel insights on the turbulent dynamics in the KHI.

Published
2016
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28. Observations of Large-Amplitude, Parallel, Electrostatic Waves Associated with the Kelvin-Helmholtz Instability by the Magnetospheric Multiscale Mission

Author

Wilder, F. D, Ergun, R. E, Schwartz, S. J, Newman, D. L, Eriksson, S, Stawarz, J. E, Goldman, M. V, Goodrich, K. A, Gershman, D. J, Malaspina, D, Holmes, J. C, Sturner, A. P, Burch, J. L, Torbert, R. B, Lindqvist, P.-A, Marklund, G. T, Khotyaintsev, Y, Strangeway, R. J, Russell, C. T, Pollock, C. J, Giles, B. L, Dorrelli, J. C, Avanov, L. A, Patterson, W. R, Plaschke, F, and Magnes, W

Subjects
Plasma Physics
Abstract

On 8 September 2015, the four Magnetospheric Multiscale spacecraft encountered a Kelvin-Helmholtz unstable magnetopause near the dusk flank. The spacecraft observed periodic compressed current sheets, between which the plasma was turbulent. We present observations of large-amplitude (up to 100 mVm) oscillations in the electric field. Because these oscillations are purely parallel to the background magnetic field, electrostatic, and below the ion plasma frequency, they are likely to be ion acoustic-like waves. These waves are observed in a turbulent plasma where multiple particle populations are intermittently mixed, including cold electrons with energies less than 10 eV. Stability analysis suggests a cold electron component is necessary for wave growth.

Published
2016
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29. Magnetospheric Multiscale Observations of Large-Amplitude Parallel, Electrostatic Waves Associated with Magnetic Reconnection at the Magnetopause

Author

Ergun, R. E, Holmes, J. C, Goodrich, K. A, Wilder, F. D, Stawarz, J. E, Eriksson, S, Newman, D. L, Schwartz, S. J, Goldman, M. V, Sturner, A. P, Pollock, C. J, Giles, B. L, Dorelli, J. J. C, Avanov, L, and Hesse, M

Subjects
Plasma Physics
Abstract

We report observations from the Magnetospheric Multiscale satellites of large-amplitude, parallel, electrostatic waves associated with magnetic reconnection at the Earth's magnetopause. The observed waves have parallel electric fields (E(sub parallel)) with amplitudes on the order of 100 mV/m and display nonlinear characteristics that suggest a possible net E(sub parallel). These waves are observed within the ion diffusion region and adjacent to (within several electron skin depths) the electron diffusion region. They are in or near the magnetosphere side current layer. Simulation results support that the strong electrostatic linear and nonlinear wave activities appear to be driven by a two stream instability, which is a consequence of mixing cold (less than 10eV) plasma in the magnetosphere with warm (approximately 100eV) plasma from the magnetosheath on a freshly reconnected magnetic field line. The frequent observation of these waves suggests that cold plasma is often present near the magnetopause.

Published
2016
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30. Magnetospheric Multiscale Satellites Observations of Parallel Electric Fields Associated with Magnetic Reconnection

Author

Ergun, R. E, Goodrich, K. A, Wilder, F. D, Holmes, J. C, Stawarz, J. E, Eriksson, S, Sturner, A. P, Malaspina, D. M, Usanova, M. E, Torbert, R. B, Lindqvist, P.-A, Khotyaintsev, Y, Burch, J. L, Strangeway, R. J, Russell, C. T, Pollock, C. J, Giles, B. L, Hesse, M, Chen, L. J, Lapenta, G, Goldman, M. V, Newman, D. L, Schwartz, S. J, Eastwood, J. P, Phan, T. D, Mozer, F. S, Drake, J, Shay, M. A, Cassak, P. A, Nakamura, R, and Marklund, G

Subjects
Geophysics
Abstract

We report observations from the Magnetospheric Multiscale satellites of parallel electric fields (E (sub parallel)) associated with magnetic reconnection in the subsolar region of the Earth's magnetopause. E (sub parallel) events near the electron diffusion region have amplitudes on the order of 100 millivolts per meter, which are significantly larger than those predicted for an antiparallel reconnection electric field. This Letter addresses specific types of E (sub parallel) events, which appear as large-amplitude, near unipolar spikes that are associated with tangled, reconnected magnetic fields. These E (sub parallel) events are primarily in or near a current layer near the separatrix and are interpreted to be double layers that may be responsible for secondary reconnection in tangled magnetic fields or flux ropes. These results are telling of the three-dimensional nature of magnetopause reconnection and indicate that magnetopause reconnection may be often patchy and/or drive turbulence along the separatrix that results in flux ropes and/or tangled magnetic fields.

Published
2016
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31. Mapping MMS Observations of Solitary Waves in Earth’s Magnetic Field

Author

Hansel, P. J., primary, Wilder, F. D., additional, Malaspina, D.M., additional, Ergun, R. E., additional, Ahmadi, N., additional, Holmes, J.C., additional, Goodrich, K. A., additional, Fuselier, S., additional, Giles, B., additional, Russell, C. T., additional, Torbert, R., additional, Strangeway, R., additional, Khotyaintsev, Y., additional, Lindqvist, P.‐A., additional, and Burch, J., additional

Published
2021
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33. Electron Bernstein waves and narrowband plasma waves near the electron cyclotron frequency in the near-Sun solar wind

Author

Malaspina, D. M., primary, Wilson III, L. B., additional, Ergun, R. E., additional, Bale, S. D., additional, Bonnell, J. W., additional, Goodrich, K., additional, Goetz, K., additional, Harvey, P. R., additional, MacDowall, R. J., additional, Pulupa, M., additional, Halekas, J., additional, Case, A., additional, Kasper, J. C., additional, Larson, D., additional, Stevens, M., additional, and Whittlesey, P., additional

Published
2021
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34. Wave-particle energy transfer directly observed in an ion cyclotron wave

Author

Vech, D., primary, Martinović, M. M., additional, Klein, K. G., additional, Malaspina, D. M., additional, Bowen, T. A., additional, Verniero, J. L., additional, Paulson, K., additional, Dudok de Wit, T., additional, Kasper, J. C., additional, Huang, J., additional, Stevens, M. L., additional, Case, A. W., additional, Korreck, K., additional, Mozer, F. S., additional, Goodrich, K. A., additional, Bale, S. D., additional, Whittlesey, P. L., additional, Livi, R., additional, Larson, D. E., additional, Pulupa, M., additional, Bonnell, J., additional, Harvey, P., additional, Goetz, K., additional, and MacDowall, R., additional

Published
2021
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35. Narrowband oblique whistler-mode waves: comparing properties observed by Parker Solar Probe at <0.3 AU and STEREO at 1 AU

Author

Cattell, C., primary, Short, B., additional, Breneman, A., additional, Halekas, J., additional, Whittesley, P., additional, Larson, D., additional, Kasper, J. C., additional, Stevens, M., additional, Case, T., additional, Moncuquet, M., additional, Bale, S., additional, Bonnell, J., additional, Dudok de Wit, T., additional, Goetz, K., additional, Harvey, P., additional, MacDowall, R., additional, Malaspina, D., additional, Maksimovic, M., additional, Pulupa, M., additional, and Goodrich, K., additional

Published
2021
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36. Mapping MMS Observations of Solitary Waves in Earth's Magnetic Field

Author

Hansel, P. J., Wilder, F. D., Malaspina, D. M., Ergun, R. E., Ahmadi, N., Holmes, J. C., Goodrich, K. A., Fuselier, S., Giles, B., Russell, C. T., Torbert, R., Strangeway, R., Khotyaintsev, Yuri V., Lindqvist, P-A, Burch, J., Hansel, P. J., Wilder, F. D., Malaspina, D. M., Ergun, R. E., Ahmadi, N., Holmes, J. C., Goodrich, K. A., Fuselier, S., Giles, B., Russell, C. T., Torbert, R., Strangeway, R., Khotyaintsev, Yuri V., Lindqvist, P-A, and Burch, J.

Abstract

Electrostatic solitary waves (ESWs) are a type of nonlinear time-domain plasma structure (TDS) generally defined by bipolar electric fields and propagation parallel to the local magnetic field. Formation mechanisms for TDSs in the magnetosphere have been studied extensively and are associated with plasma boundary layers and the braking of bursty bulk flows (BBFs). However, the rapid timescales over which these TDSs occur (<2 ms) make them infeasible to count by eye over large time periods. Furthermore, high-cadence data are not always available. The Solitary Wave Detector (SWD) on NASA's Magnetospheric Multiscale (MMS) mission quantifies the occurrence and amplitude of TDS throughout the constellation's orbit; analysis of burst (65 kS/s) parallel electric field data indicates that the SWD captures approximately 60% of all bipolar TDS encountered in the tail region, enabling large-scale examination of their occurrence. Maps of TDS occurrence rates during several years of the MMS mission were generated from SWD data, showing enhanced TDS density in the tail region between 6 and 9 Re; enhance occurrence in or near shocks; and an unexpected enhancement in the dawn side of the tail and in the radiation belt.

Published
2021
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37. The Interstellar Boundary Explorer Science Operations Center

Author

Schwadron, N. A., Crew, G., Vanderspek, R., Allegrini, F., Bzowski, M., DeMagistre, R., Dunn, G., Funsten, H., Fuselier, S. A., Goodrich, K., Gruntman, M., Hanley, J., Heerikuisen, J., Heirtlzer, D., Janzen, P., Kucharek, H., Loeffler, C., Mashburn, K., Maynard, K., McComas, D. J., Moebius, E., Prested, C., Randol, B., Reisenfeld, D., Reno, M., Roelof, E., and Wu, P.

Published
2009
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38. Parker Solar Probe Evidence for Scattering of Electrons in the Young Solar Wind by Narrowband Whistler-mode Waves

Author

Cattell, C., primary, Breneman, A., additional, Dombeck, J., additional, Short, B., additional, Wygant, J., additional, Halekas, J., additional, Case, Tony, additional, Kasper, J. C., additional, Larson, D., additional, Stevens, Mike, additional, Whittesley, P., additional, Bale, S. D., additional, Dudok de Wit, T., additional, Goodrich, K., additional, MacDowall, R., additional, Moncuquet, M., additional, Malaspina, D., additional, and Pulupa, M., additional

Published
2021
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39. Direct Multipoint Observations Capturing the Reformation of a Supercritical Fast Magnetosonic Shock

Author

Turner, D. L., primary, Wilson, L. B., additional, Goodrich, K. A., additional, Madanian, H., additional, Schwartz, S. J., additional, Liu, T. Z., additional, Johlander, A., additional, Caprioli, D., additional, Cohen, I. J., additional, Gershman, D., additional, Hietala, H., additional, Westlake, J. H., additional, Lavraud, B., additional, Le Contel, O., additional, and Burch, J. L., additional

Published
2021
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40. Evidence of Sub-proton-scale Magnetic Holes in the Venusian Magnetosheath

Author

Goodrich, K., Bonnell, J. W., Curry, S., Livi, R., Whittlesey, P. L., Mozer, F., Malaspina, D., Bale, S. D., Bowen, T. A., Case, A. W., Dudok de Wit, Thierry, Goetz, K., Halekas, J. S., Harvey, P., Kasper, J. C., Larson, D. E., Macdowall, R. J., Mcmanus, M., Pulupa, M., Stevens, M. L., and POTHIER, Nathalie

Subjects
[SDU] Sciences of the Universe [physics], MAGNETOSPHERIC PHYSICS, IONOSPHERE, Planetary ionospheres, Magnetospheric configuration and dynamics, Planetary magnetospheres
Abstract

We present the first evidence of sub-proton-scale magnetic holes in the Venusian magnetosheath. Depressions in magnetic field strength, commonly referred to as magnetic holes, are observed ubiquitously in space plasmas. Magnetic holes with spatial scales larger than the local proton gyroradius (ρ) are usually attributed to the mirror instability. Those smaller than or on the order of ρ, termed "sub-proton-scale" magnetic holes, are likely supported by electron currents vortices, rotating perpendicular to the ambient magnetic field. While there are numerous accounts of sub-proton-scale magnetic holes within the Earth's magnetosphere, there are no reported observations in other space plasma environments. During Parker Solar Probe's first Venus Gravity Assist, the spacecraft crossed the planet's bow shock and subsequently observed the Venusian magnetosheath. The FIELDS instrument suite onboard the spacecraft achieved magnetic and electric field measurements of magnetic hole structures. The electric field associated with magnetic depressions are consistent with electron current vortices with amplitudes on the order of 1μA/m2. This observation suggests sub-proton-scale magnetic holes are signatures of a universal process in space plasmas.

Published
2020

41. Whistler Waves in the Inner Heliosphere

Author

Page, B., Bale, S., Bowen, T. A., Dudok de Wit, Thierry, Goodrich, K., Malaspina, D., Pulupa, M., and POTHIER, Nathalie

Subjects
ASTROPHYSICS, Turbulence, [SDU] Sciences of the Universe [physics], Wave/particle interactions, SPACE PLASMA PHYSICS, Corona, ASTRONOMY, SOLAR PHYSICS, Kinetic and MHD theory
Abstract

During its first 174 days at heliocentric distances less than 0.5 au, Parker Solar Probe encountered hundreds of narrowband electromagnetic wave bursts in the whistler frequency range. These events typically lasted on the order of minutes, although narrowband storms lasting longer than one hour were observed as well. The FIELDS instrument measures two components of the electric field and two components of the magnetic field of each wave - here we describe an analysis method for determining polarization and propagation direction with this limited information. The waves are shown to be circularly polarized and to rotate in a right-handed sense around the background magnetic field, confirming their identification as whistlers. Their propagation directions are shown to be approximately collinear with the background magnetic field, although ambiguity remains as to whether they are anti-parallel or parallel. Future data will allow the analysis method to resolve this ambiguity, which is a critical step toward identifying Doppler-shifted cyclotron resonances between the waves and strahl electrons.

Published
2020

42. The Near-Sun Dust Environment as Seen by Parker Solar Probe

Author

Malaspina, D., Szalay, J. R., Pokorny, P., Pusack, A., Page, B., Bale, S. D., Bonnell, J. W., Dudok de Wit, Thierry, Goetz, K., Goodrich, K., Harvey, P., Macdowall, R. J., Pulupa, M., and POTHIER, Nathalie

Subjects
[SDU] Sciences of the Universe [physics], PLANETARY SCIENCES: SOLAR SYSTEM OBJECTS, IONOSPHERE, Rings and dust, Dust, Meteor-trail physics, PLANETARY SCIENCES: COMETS AND SMALL BODIES, PLANETARY SCIENCES: FLUID PLANETS
Abstract

Over the last two years, and six near-Sun encounter orbits, the Parker Solar Probe spacecraft has provided the first in-situ observations of interplanetary dust closer than ~0.3 AU from the Sun. Dust is detected by the FIELDS instrument via impact ionization and subsequent perturbations to the plasma environment close to the spacecraft. FIELDS observations yield count rates, impact amplitudes, and impact directionality information. Interpreting these data to arrive at new understanding of dust dynamics of the inner heliosphere requires combining state-of-the-art modeling and theory with detailed FIELDS instrument knowledge. In this talk, we describe recent results related to the near-Sun dust environment, including: bounding the location and rate of beta-meteoroid production, the interaction of debris streams with near-Sun dust, the density of near-circular dust near the Sun, hints of dust sublimation close to the Sun, and the effects of instrument operation on dust impact detection. The Parker Solar Probe FIELDS data provide an in-situ window into stellar processing of dust in the near-Sun plasma environment, and we are beginning to understand what we see.

Published
2020

43. Double Layers: Kinetic Plasma Physics at the Venusian Bow Shock

Author

Malaspina, D., Goodrich, K., Halekas, J. S., Livi, R., Mcmanus, M., Curry, S., Bale, S., Bonnell, J. W., Dudok de Wit, Thierry, Goetz, K., Harvey, P., Macdowall, R. J., Pulupa, M., Case, A. W., Kasper, J. C., Korreck, K. E., Larson, D. E., Stevens, M. L., Whittlesey, P. L., and POTHIER, Nathalie

Subjects
Shock waves, [SDU] Sciences of the Universe [physics], SPACE PLASMA PHYSICS, Particle acceleration, Kinetic waves and instabilities, Plasma energization
Abstract

The induced magnetosphere of Venus presents an obstacle to the solar wind. At the flow-obstacle interface, plasma is slowed, deflected, and heated. Based on observations of Earth's bow shock and magnetosheath, kinetic plasma processes are expected to play an important role in these dynamics at Venus. However, these processes have gone largely undetected at Venus due to the small number of measurements at sufficiently high sampling cadences. Using data from a Parker Solar Probe encounter with Venus, this study demonstrates the existence of kinetic-scale electric field structures, including plasma double layers, at the outer edge of the Venusian magnetosheath. Many of the double layers have signatures of developed two-stream instabilities and phase space holes. Double layer spatial scales are consistent with those reported at Earth. Estimated potential drops are similar to the electron temperature change across the bow shock, consistent with double layers driven by mixing of inhomogeneous plasmas at the magnetosheath boundary. A large number of distinct double layers are found in few burst captures, implying that double layers, and the waves that they drive, have higher amplitudes relative to other high frequency bow shock and magnetosheath waves at Venus as compared to Earth. These are the first direct observations of plasma double layers beyond near-Earth space, demonstrating that kinetic plasma processes are active in diverse plasma environments, and can be identified when high cadence observations are available.

Published
2020

44. Observations of Particle Acceleration in Magnetic Reconnection-driven Turbulence

Author

Ergun, R. E., Ahmadi, N., Kromyda, L., Schwartz, S. J., Chasapis, A., Hoilijoki, S., Wilder, F. D., Stawarz, J. E., Goodrich, K. A., Turner, D. L., Cohen, I. J., Bingham, S. T., Holmes, J. C., Nakamura, R., Pucci, F., Torbert, R. B., Burch, J. L., Lindqvist, Per-Arne, Strangeway, R. J., Le Contel, O., Giles, B. L., Ergun, R. E., Ahmadi, N., Kromyda, L., Schwartz, S. J., Chasapis, A., Hoilijoki, S., Wilder, F. D., Stawarz, J. E., Goodrich, K. A., Turner, D. L., Cohen, I. J., Bingham, S. T., Holmes, J. C., Nakamura, R., Pucci, F., Torbert, R. B., Burch, J. L., Lindqvist, Per-Arne, Strangeway, R. J., Le Contel, O., and Giles, B. L.

Abstract

The Magnetospheric Multiscale Mission observes, in detail, charged particle heating and substantial nonthermal acceleration in a region of strong turbulence (vertical bar delta B vertical bar/vertical bar B vertical bar similar to 1, where B is the magnetic field) that surrounds a magnetic reconnection X-line. Magnetic reconnection enables magnetic field annihilation in a volume that far exceeds that of the diffusion region. The formidable magnetic field annihilation breaks into strong, intermittent turbulence with magnetic field energy as the driver. The strong, intermittent turbulence appears to generate the necessary conditions for nonthermal acceleration. It creates intense, localized currents (J) and unusually large-amplitude electric fields (E). The combination of turbulence-generated E and J results in a significant net positive mean of J center dot E, which signifies particle energization. Ion and electron heating rates are such that they experience a fourfold increase from their initial temperature. Importantly, the strong turbulence also generates magnetic holes or depletions in vertical bar B vertical bar that can trap particles. Trapping considerably increases the dwell time of a subset of particles in the turbulent region, which results in significant nonthermal particle acceleration. The direct observation of strong turbulence that is enabled by magnetic reconnection with nonthermal particle acceleration has far-reaching implications, since turbulence in plasmas is pervasive and may occupy significant volumes of the interstellar medium and intergalactic space. For example, strong turbulence from magnetic field annihilation in the supernova nebulae may dominate large volumes. As such, this observed energization process could plausibly contribute to the supply and development of the cosmic-ray spectrum., QC 20201126

Published
2020
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45. Lower Hybrid Drift Waves and Electromagnetic Electron Space-Phase Holes Associated With Dipolarization Fronts and Field-Aligned Currents Observed by the Magnetospheric Multiscale Mission During a Substorm

Author

Le, Contel O., Breuillard, H., Argall, M. R., Graham, D. B., Fischer, D., Retino, A., Berthomier, M., Pottelette, R., Mirioni, L., Chust, T., Wilder, F. D., Gershman, D. J., Varsani, A., Lindqvist, P. -A., Khotyaintsev, Yu. V., Norgren, C., Ergun, R. E., Goodrich, K. A., Burch, J. L., Torbert, R. B., Needell, J., Chutter, M., Rau, D., Dors, I., Russell, C. T., Magnes, W., Strangeway, R. J., Bromund, K. R., Wei, H. Y., Plaschke, F., Anderson, B. J., Le, G., Moore, T. E., Giles, B. L., Paterson, W. R., Pollock, C. J., Dorelli, J. C., Avanov, L. A., Lavraud, B., Fuselier, S. A., Mauk, B. H., Cohen, I. J., Turner, D. L., Fennell, J. F., Leonard, T., Jaynes, A. N., Nakamura, Rumi, and Saito, Yoshifumi

Abstract

著者人数: 48名, Accepted: 2017-10-10, 資料番号: SA1170207000

Published
2017

46. Kinetic‐Scale Turbulence in the Venusian Magnetosheath

Author

Bowen, T. A., primary, Bale, S. D., additional, Bandyopadhyay, R., additional, Bonnell, J. W., additional, Case, A., additional, Chasapis, A., additional, Chen, C. H. K., additional, Curry, S., additional, Dudok de Wit, T., additional, Goetz, K., additional, Goodrich, K., additional, Gruesbeck, J., additional, Halekas, J., additional, Harvey, P. R., additional, Howes, G. G., additional, Kasper, J. C., additional, Korreck, K., additional, Larson, D., additional, Livi, R., additional, MacDowall, R. J., additional, Malaspina, D. M., additional, Mallet, A., additional, McManus, M. D., additional, Page, B., additional, Pulupa, M., additional, Raouafi, N., additional, Stevens, M. L., additional, and Whittlesey, P., additional

Published
2021
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48. The Interstellar Boundary Explorer Science Operations Center

Author

Schwadron, N. A., primary, Crew, G., additional, Vanderspek, R., additional, Allegrini, F., additional, Bzowski, M., additional, DeMagistre, R., additional, Dunn, G., additional, Funsten, H., additional, Fuselier, S. A., additional, Goodrich, K., additional, Gruntman, M., additional, Hanley, J., additional, Heerikuisen, J., additional, Heirtlzer, D., additional, Janzen, P., additional, Kucharek, H., additional, Loeffler, C., additional, Mashburn, K., additional, Maynard, K., additional, McComas, D. J., additional, Moebius, E., additional, Prested, C., additional, Randol, B., additional, Reisenfeld, D., additional, Reno, M., additional, Roelof, E., additional, and Wu, P., additional

Published
2009
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50. Particle Acceleration in Strong Turbulence in the Earth’s Magnetotail

Author

Ergun, R. E., primary, Ahmadi, N., additional, Kromyda, L., additional, Schwartz, S. J., additional, Chasapis, A., additional, Hoilijoki, S., additional, Wilder, F. D., additional, Cassak, P. A., additional, Stawarz, J. E., additional, Goodrich, K. A., additional, Turner, D. L., additional, Pucci, F., additional, Pouquet, A., additional, Matthaeus, W. H., additional, Drake, J. F., additional, Hesse, M., additional, Shay, M. A., additional, Torbert, R. B., additional, and Burch, J. L., additional

Published
2020
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