Your search keyword '"Whittlesey, Phyllis"' showing total 251 results

1. Closed magnetic topology in the Venusian magnetotail and ion escape at Venus.

Author

Xu, Shaosui, Mitchell, David, Whittlesey, Phyllis, Rahmati, Ali, Livi, Roberto, Larson, Davin, Luhmann, Janet, Halekas, Jasper, Hara, Takuya, McFadden, James, Pulupa, Marc, Bale, Stuart, Curry, Shannon, and Persson, Moa

Abstract

Venus, lacking an intrinsic global dipole magnetic field, serves as a textbook example of an induced magnetosphere, formed by interplanetary magnetic fields (IMF) enveloping the planet. Yet, various aspects of its magnetospheric dynamics and planetary ion outflows are complex and not well understood. Here we analyze plasma and magnetic field data acquired during the fourth Venus flyby of the Parker Solar Probe (PSP) mission and show evidence for closed topology in the nightside and downstream portion of the Venus magnetosphere (i.e., the magnetotail). The formation of the closed topology involves magnetic reconnection-a process rarely observed at non-magnetized planets. In addition, our study provides an evidence linking the cold Venusian ion flow in the magnetotail directly to magnetic connectivity to the ionosphere, akin to observations at Mars. These findings not only help the understanding of the complex ion flow patterns at Venus but also suggest that magnetic topology is one piece of key information for resolving ion escape mechanisms and thus the atmospheric evolution across various planetary environments and exoplanets.

Published

2024

2. Probing Turbulent Scattering Effects on Suprathermal Electrons in the Solar Wind: Modeling, Observations and Implications

Author

Zaslavsky, Arnaud, Kasper, Justin C., Kontar, Eduard P., Larson, Davin E., Maksimovic, Milan, Marques, José M. D. C., Nicolaou, Georgios, Owen, Christopher J., Romeo, Orlando, and Whittlesey, Phyllis L.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

This study explores the impact of a turbulent scattering mechanism, akin to those influencing solar and galactic cosmic rays propagating in the interplanetary medium, on the population of suprathermal electrons in the solar wind. We employ a Fokker-Planck equation to model the radial evolution of electron pitch angle distributions under the action of magnetic focusing, which moves the electrons away from isotropy, and of a diffusion process that tends to bring them back to it. We compare the steady-state solutions of this Fokker-Planck equation with data obtained from the Solar Orbiter and Parker Solar Probe missions and find a remarkable agreement, varying the turbulent mean free path as the sole free parameter in our model. The obtained mean free paths are of the order of the astronomical unit, and display weak dependence on electron energy within the $100$ eV to $1$ keV range. This value is notably lower than Coulomb collision estimates but aligns well with observed mean free paths of low-rigidity solar energetic particles events. The strong agreement between our model and observations leads us to conclude that the hypothesis of turbulent scattering at work on electrons at all heliospheric distances is justified. We discuss several implications, notably the existence of a low Knudsen number region at large distances from the Sun, which offers a natural explanation for the presence of an isotropic ``halo'' component at all distances from the Sun -- electrons being isotropized in this distant region before travelling back into the inner part of the interplanetary medium., Comment: 23 pages, 13 figures, 1 table

Published

2024

3. On the Mesoscale Structure of CMEs at Mercury's Orbit: BepiColombo and Parker Solar Probe Observations

Author

Palmerio, Erika, Carcaboso, Fernando, Khoo, Leng Ying, Salman, Tarik M., Sánchez-Cano, Beatriz, Lynch, Benjamin J., Rivera, Yeimy J., Pal, Sanchita, Nieves-Chinchilla, Teresa, Weiss, Andreas J., Lario, David, Mieth, Johannes Z. D., Heyner, Daniel, Stevens, Michael L., Romeo, Orlando M., Zhukov, Andrei N., Rodriguez, Luciano, Lee, Christina O., Cohen, Christina M. S., Rodríguez-García, Laura, Whittlesey, Phyllis L., Dresing, Nina, Oleynik, Philipp, Jebaraj, Immanuel C., Fischer, David, Schmid, Daniel, Richter, Ingo, Auster, Hans-Ulrich, Fraschetti, Federico, and Mierla, Marilena

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics, Physics - Space Physics

Abstract

On 2022 February 15, an impressive filament eruption was observed off the solar eastern limb from three remote-sensing viewpoints, namely Earth, STEREO-A, and Solar Orbiter. In addition to representing the most-distant observed filament at extreme ultraviolet wavelengths -- captured by Solar Orbiter's field of view extending to above 6 $R_{\odot}$ -- this event was also associated with the release of a fast ($\sim$2200 km$\cdot$s$^{-1}$) coronal mass ejection (CME) that was directed towards BepiColombo and Parker Solar Probe. These two probes were separated by 2$^{\circ}$ in latitude, 4$^{\circ}$ in longitude, and 0.03 au in radial distance around the time of the CME-driven shock arrival in situ. The relative proximity of the two probes to each other and to the Sun ($\sim$0.35 au) allows us to study the mesoscale structure of CMEs at Mercury's orbit for the first time. We analyse similarities and differences in the main CME-related structures measured at the two locations, namely the interplanetary shock, the sheath region, and the magnetic ejecta. We find that, despite the separation between the two spacecraft being well within the typical uncertainties associated with determination of CME geometric parameters from remote-sensing observations, the two sets of in-situ measurements display some profound differences that make understanding of the overall 3D CME structure particularly challenging. Finally, we discuss our findings within the context of space weather at Mercury's distances and in terms of the need to investigate solar transients via spacecraft constellations with small separations, which has been gaining significant attention during recent years., Comment: 31 pages, 13 figures, 5 tables, accepted for publication in The Astrophysical Journal

Published

2024

4. Proton and Alpha Driven Instabilities in an Ion Cyclotron Wave Event

Author

McManus, Michael D., Klein, Kristopher G., Larson, Davin, Bale, Stuart D., Bowen, Trevor A., Huang, Jia, Livi, Roberto, Rahmati, Ali, Romeo, Orlando, Verniero, Jaye, and Whittlesey, Phyllis

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Ion scale wave events or "wave storms" in the solar wind are characterised by enhancements in magnetic field fluctuations as well as coherent magnetic field polarisation signatures at or around the local ion cyclotron frequencies. In this paper we study in detail one such wave event from Parker Solar Probe's (PSP) fourth encounter, consisting of an initial period of left-handed (LH) polarisation abruptly transitioning to a strong period of right-handed (RH) polarisation, accompanied by clear core-beam structure in both the alpha and proton velocity distribution functions. A linear stability analysis shows that the LH polarised waves are anti-Sunward propagating Alfv\'en/ion cyclotron (A/IC) waves primarily driven by a proton cyclotron instability in the proton core population, and the RH polarised waves are anti-Sunward propagating fast magnetosonic/whistler (FM/W) waves driven by a firehose-like instability in the secondary alpha beam population. The abrupt transition from LH to RH is caused by a drop in the proton core temperature anisotropy. We find very good agreement between the frequencies and polarisations of the unstable wave modes as predicted by linear theory and those observed in the magnetic field spectra. Given the ubiquity of ion scale wave signatures observed by PSP, this work gives insight into which exact instabilities may be active and mediating energy transfer in wave-particle interactions in the inner heliosphere, as well as highlighting the role a secondary alpha population may play as a rarely considered source of free energy available for producing wave activity.

Published

2023

5. Are Switchback boundaries observed by Parker Solar Probe closed?

Author

Bizien, Nina, de Wit, Thierry Dudok, Froment, Clara, Velli, Marco, Case, Anthony W., Bale, Stuart D., Kasper, Justin, Whittlesey, Phyllis, MacDowall, Robert, and Larson, Davin

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics, Physics - Plasma Physics, Physics - Space Physics

Abstract

Switchbacks are sudden and large deflections in the magnetic field that Parker Solar Probe frequently observes in the inner heliosphere. Their ubiquitous occurrence has prompted numerous studies to determine their nature and origin. Our goal is to describe the boundary of these switchbacks using a series of events detected during the spacecraft's first encounter with the Sun. Using FIELDS and SWEAP data, we investigate different methods for determining the boundary normal. The observed boundaries are arc-polarized structures with a rotation that is always contained in a plane. Classical minimum variance analysis (MVA) gives misleading results and overestimates the number of rotational discontinuities. We propose a robust geometric method to identify the nature of these discontinuities, which involves determining whether or not the plane that contains them also includes the origin ($\textbf{B}=0$). Most boundaries appear to have the same characteristics as tangential discontinuities in the context of switchbacks, with little evidence for having rotational discontinuities. We find no effect of the size of the Parker spiral deviation. Furthermore, the thickness of the boundary is within MHD scales. We conclude that most of the switchback boundaries observed by Parker Solar Probe are likely to be closed, in contrast to previous studies. Our results suggest that their erosion may be much slower than expected., Comment: 11 pages, 6 figures, Animations available at https://doi.org/10.5281/zenodo.8424748

Published

2023

6. The Need for Near-Earth Multi-Spacecraft Heliospheric Measurements and an Explorer Mission to Investigate Interplanetary Structures and Transients in the Near-Earth Heliosphere.

Author

Lugaz, Noé, Lee, Christina, Al-Haddad, Nada, Lillis, Robert, Jian, Lan, Curtis, David, Galvin, Antoinette, Whittlesey, Phyllis, Rahmati, Ali, Zesta, Eftyhia, Moldwin, Mark, Summerlin, Errol, Larson, Davin, Courtade, Sasha, French, Richard, Hunter, Richard, Covitti, Federico, Cosgrove, Daniel, Prall, J, Allen, Robert, Zhuang, Bin, Winslow, Réka, Scolini, Camilla, Lynch, Benjamin, Filwett, Rachael, Palmerio, Erika, Farrugia, Charles, Smith, Charles, Möstl, Christian, Weiler, Eva, Janvier, Miho, Regnault, Florian, Livi, Roberto, and Nieves-Chinchilla, Teresa

Subjects

Coronal mass ejection, Interplanetary space, Mission concept

Abstract

Based on decades of single-spacecraft measurements near 1 au as well as data from heliospheric and planetary missions, multi-spacecraft simultaneous measurements in the inner heliosphere on separations of 0.05-0.2 au are required to close existing gaps in our knowledge of solar wind structures, transients, and energetic particles, especially coronal mass ejections (CMEs), stream interaction regions (SIRs), high speed solar wind streams (HSS), and energetic storm particle (ESP) events. The Mission to Investigate Interplanetary Structures and Transients (MIIST) is a concept for a small multi-spacecraft mission to explore the near-Earth heliosphere on these critical scales. It is designed to advance two goals: (a) to determine the spatiotemporal variations and the variability of solar wind structures, transients, and energetic particle fluxes in near-Earth interplanetary (IP) space, and (b) to advance our fundamental knowledge necessary to improve space weather forecasting from in situ data. We present the scientific rationale for this proposed mission, the science requirements, payload, implementation, and concept of mission operation that address a key gap in our knowledge of IP structures and transients within the cost, launch, and schedule limitations of the NASA Heliophysics Small Explorers program.

Published

2024

7. Reimagining Heliophysics: A bold new vision for the next decade and beyond

Author

Cohen, Ian J., Baker, Dan, Bortnik, Jacob, Brandt, Pontus, Burch, Jim, Caspi, Amir, Clark, George, Cohen, Ofer, DeForest, Craig, Emslie, Gordon, Gkioulidou, Matina, Halford, Alexa, Higginson, Aleida, Jaynes, Allison, Klein, Kristopher, Kletzing, Craig, McGranaghan, Ryan, Miles, David, Nikoukar, Romina, Nykyrii, Katariina, Paxton, Larry, Prockter, Louise, Spence, Harlan, Swartz, William H., Turner, Drew L., Westlake, Joe, Whittlesey, Phyllis, and Wiltberger, Michael

Subjects

Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics

Abstract

The field of Heliophysics has a branding problem. We need an answer to the question: ``What is Heliophysics\?'', the answer to which should clearly and succinctly defines our science in a compelling way that simultaneously introduces a sense of wonder and exploration into our science and our missions. Unfortunately, recent over-reliance on space weather to define our field, as opposed to simply using it as a practical and relatable example of applied Heliophysics science, narrows the scope of what solar and space physics is and diminishes its fundamental importance. Moving forward, our community needs to be bold and unabashed in our definition of Heliophysics and its big questions. We should emphasize the general and fundamental importance and excitement of our science with a new mindset that generalizes and expands the definition of Heliophysics to include new ``frontiers'' of increasing interest to the community. Heliophysics should be unbound from its current confinement to the Sun-Earth connection and expanded to studies of the fundamental nature of space plasma physics across the solar system and greater cosmos. Finally, we need to come together as a community to advance our science by envisioning, prioritizing, and supporting -- with a unified voice -- a set of bold new missions that target compelling science questions - even if they do not explore the traditional Sun- and Earth-centric aspects of Heliophysics science. Such new, large missions to expand the frontiers and scope of Heliophysics science large missions can be the key to galvanizing the public and policymakers to support the overall Heliophysics program.

Published

2023

8. HelioSwarm: A Multipoint, Multiscale Mission to Characterize Turbulence

Author

Klein, Kristopher G., Spence, Harlan, Alexandrova, Olga, Argall, Matthew, Arzamasskiy, Lev, Bookbinder, Jay, Broeren, Theodore, Caprioli, Damiano, Case, Anthony, Chandran, Benjamin, Chen, Li-Jen, Dors, Ivan, Eastwood, Jonathan, Forsyth, Colin, Galvin, Antoinette, Genot, Vincent, Halekas, Jasper, Hesse, Michael, Hine, Butler, Horbury, Tim, Jian, Lan, Kasper, Justin, Kretzschmar, Matthieu, Kunz, Matthew, Lavraud, Benoit, Contel, Olivier Le, Mallet, Alfred, Maruca, Bennett, Matthaeus, William, Niehof, Jonathan, O'Brian, Helen, Owen, Christopher, Retino, Alessandro, Reynolds, Christopher, Roberts, Owen, Schekochihin, Alexander, Skoug, Ruth, Smith, Charles, Smith, Sonya, Steinberg, John, Stevens, Michael, Szabo, Adam, TenBarge, Jason, Torbert, Roy, Vasquez, Bernard, Verscharen, Daniel, Whittlesey, Phyllis, Wickizer, Brittany, Zank, Gary, and Zweibel, Ellen

Subjects

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

Abstract

HelioSwarm (HS) is a NASA Medium-Class Explorer mission of the Heliophysics Division designed to explore the dynamic three-dimensional mechanisms controlling the physics of plasma turbulence, a ubiquitous process occurring in the heliosphere and in plasmas throughout the universe. This will be accomplished by making simultaneous measurements at nine spacecraft with separations spanning magnetohydrodynamic and sub-ion spatial scales in a variety of near-Earth plasmas. In this paper, we describe the scientific background for the HS investigation, the mission goals and objectives, the observatory reference trajectory and instrumentation implementation before the start of Phase B. Through multipoint, multiscale measurements, HS promises to reveal how energy is transferred across scales and boundaries in plasmas throughout the universe., Comment: Submitted to Space Science Reviews, 60 pages, 15 figures, 2 videos

Published

2023

9. Multi-point Assessment of the Kinematics of Shocks (MAKOS): A Heliophysics Mission Concept Study

Author

Goodrich, Katherine A., Wilson III, Lynn B., Schwartz, Steven, Cohen, Ian J., Turner, Drew L., Whittlesey, Phyllis, Caspi, Amir, Rose, Randall, and Smith, Keith

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - High Energy Astrophysical Phenomena, Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics, Physics - Space Physics

Abstract

Collisionless shocks are fundamental processes that are ubiquitous in space plasma physics throughout the Heliosphere and most astrophysical environments. Earth's bow shock and interplanetary shocks at 1 AU offer the most readily accessible opportunities to advance our understanding of the nature of collisionless shocks via fully-instrumented, in situ observations. One major outstanding question pertains to the energy budget of collisionless shocks, particularly how exactly collisionless shocks convert incident kinetic bulk flow energy into thermalization (heating), suprathermal particle acceleration, and a variety of plasma waves, including nonlinear structures. Furthermore, it remains unknown how those energy conversion processes change for different shock orientations (e.g., quasi-parallel vs. quasi-perpendicular) and driving conditions (upstream Alfv\'enic and fast Mach numbers, plasma beta, etc.). Required to address these questions are multipoint observations enabling direct measurement of the necessary plasmas, energetic particles, and electric and magnetic fields and waves, all simultaneously from upstream, downstream, and at the shock transition layer with observatory separations at ion to magnetohydrodynamic (MHD) scales. Such a configuration of spacecraft with specifically-designed instruments has never been available, and this white paper describes a conceptual mission design -- MAKOS -- to address these outstanding questions and advance our knowledge of the nature of collisionless shocks., Comment: White paper submitted to the Decadal Survey for Solar and Space Physics (Heliophysics) 2024-2033; 9 pages, 3 figures, 5 tables

Published

2023

10. The Persistent Mystery of Collisionless Shocks

Author

Goodrich, Katherine, Schwartz, Steven, Wilson III, Lynn, Cohen, Ian, Turner, Drew, Caspi, Amir, Smith, Keith, Rose, Randall, Whittlesey, Phyllis, Plaschke, Ferdinand, Halekas, Jasper, Hospodarsky, George, Burch, James, Gingell, Imogen, Chen, Li-Jen, Retino, Alessandro, and Khotyaintsev, Yuri

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - High Energy Astrophysical Phenomena, Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics, Physics - Space Physics

Abstract

Collisionless shock waves are one of the main forms of energy conversion in space plasmas. They can directly or indirectly drive other universal plasma processes such as magnetic reconnection, turbulence, particle acceleration and wave phenomena. Collisionless shocks employ a myriad of kinetic plasma mechanisms to convert the kinetic energy of supersonic flows in space to other forms of energy (e.g., thermal plasma, energetic particles, or Poynting flux) in order for the flow to pass an immovable obstacle. The partitioning of energy downstream of collisionless shocks is not well understood, nor are the processes which perform energy conversion. While we, as the heliophysics community, have collected an abundance of observations of the terrestrial bow shock, instrument and mission-level limitations have made it impossible to quantify this partition, to establish the physics within the shock layer responsible for it, and to understand its dependence on upstream conditions. This paper stresses the need for the first ever spacecraft mission specifically designed and dedicated to the observation of both the terrestrial bow shock as well as Interplanetary shocks in the solar wind., Comment: White paper submitted to the Decadal Survey for Solar and Space Physics (Heliophysics) 2024-2033; 9 pages, 4 figures

Published

2023

11. The Temperature, Electron, and Pressure Characteristics of Switchbacks: Parker Solar Probe Observations

Author

Huang, Jia, Kasper, Justin C., Larson, Davin E., McManus, Michael D., Whittlesey, Phyllis, Livi, Roberto, Rahmati, Ali, Romeo, Orlando M., Liu, Mingzhe, Jian, Lan K., Verniero, J. L., Velli, Marco, Badman, Samuel T., Rivera, Yeimy J., Niembro, Tatiana, Paulson, Kristoff, Stevens, Michael L., Case, Anthony W., Bowen, Trevor A., Pulupa, Marc, Bale, Stuart D., and Halekas, Jasper S.

Subjects

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

Abstract

Parker Solar Probe (PSP) observes unexpectedly prevalent switchbacks, which are rapid magnetic field reversals that last from seconds to hours, in the inner heliosphere, posing new challenges to understanding their nature, origin, and evolution. In this work, we investigate the thermal states, electron pitch angle distributions, and pressure signatures of both inside and outside switchbacks, separating a switchback into spike, transition region (TR), and quiet period (QP). Based on our analysis, we find that the proton temperature anisotropies in TRs seem to show an intermediate state between spike and QP plasmas. The proton temperatures are more enhanced in spike than in TR and QP, but the alpha temperatures and alpha-to-proton temperature ratios show the opposite trends, implying that the preferential heating mechanisms of protons and alphas are competing in different regions of switchbacks. Moreover, our results suggest that the electron integrated intensities are almost the same across the switchbacks but the electron pitch angle distributions are more isotropic inside than outside switchbacks, implying switchbacks are intact structures but strong scattering of electrons happens inside switchbacks. In addition, the examination of pressures reveals that the total pressures are comparable through an individual switchback, confirming switchbacks are pressure-balanced structures. These characteristics could further our understanding of ion heating, electron scattering, and the structure of switchbacks., Comment: published in ApJ

Published

2023

12. The essential role of multi-point measurements in investigations of turbulence, three-dimensional structure, and dynamics: the solar wind beyond single scale and the Taylor Hypothesis

Author

Matthaeus, W. H., Adhikari, S., Bandyopadhyay, R., Brown, M. R., Bruno, R., Borovsky, J., Carbone, V., Caprioli, D., Chasapis, A., Chhiber, R., Dasso, S., Dmitruk, P., Del Zanna, L., Dmitruk, P. A., Franci, Luca, Gary, S. P., Goldstein, M. L., Gomez, D., Greco, A., Horbury, T. S., Ji, Hantao, Kasper, J. C., Klein, K. G., Landi, S., Li, Hui, Malara, F., Maruca, B. A., Mininni, P., Oughton, Sean, Papini, E., Parashar, T. N., Pecora, F., Petrosyan, Arakel, Pouquet, Annick, Retino, A., Roberts, Owen, Ruffolo, David, Servidio, Sergio, Spence, Harlan, Smith, C. W., Stawarz, J. E., TenBarge, Jason, Vasquez, B. J., Vaivads, Andris, Valentini, F., Velli, Marco, Verdini, A., Verscharen, Daniel, Whittlesey, Phyllis, Wicks, Robert, Yang, Y., and Zimbardo, G.

Subjects

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

Abstract

Space plasmas are three-dimensional dynamic entities. Except under very special circumstances, their structure in space and their behavior in time are not related in any simple way. Therefore, single spacecraft in situ measurements cannot unambiguously unravel the full space-time structure of the heliospheric plasmas of interest in the inner heliosphere, in the Geospace environment, or the outer heliosphere. This shortcoming leaves numerous central questions incompletely answered. Deficiencies remain in at least two important subjects, Space Weather and fundamental plasma turbulence theory, due to a lack of a more complete understanding of the space-time structure of dynamic plasmas. Only with multispacecraft measurements over suitable spans of spatial separation and temporal duration can these ambiguities be resolved. We note that these characterizations apply to turbulence across a wide range of scales, and also equally well to shocks, flux ropes, magnetic clouds, current sheets, stream interactions, etc. In the following, we will describe the basic requirements for resolving space-time structure in general, using turbulence' as both an example and a principal target or study. Several types of missions are suggested to resolve space-time structure throughout the Heliosphere., Comment: White Paper submitted to: Decadal Survey for Solar and Space Physics (Heliophysics) 2024-2033. arXiv admin note: substantial text overlap with arXiv:1903.06890

Published

2022

13. Electron-driven instabilities in the solar wind

Author

Verscharen, Daniel, Chandran, Benjamin D. G., Boella, Elisabetta, Halekas, Jasper, Innocenti, Maria Elena, Jagarlamudi, Vamsee K., Micera, Alfredo, Pierrard, Viviane, Stverak, Stepan, Vasko, Ivan Y., Velli, Marco, and Whittlesey, Phyllis L.

Subjects

Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics, Physics - Geophysics, Physics - Plasma Physics

Abstract

The electrons are an essential particle species in the solar wind. They often exhibit non-equilibrium features in their velocity distribution function. These include temperature anisotropies, tails (kurtosis), and reflectional asymmetries (skewness), which contribute a significant heat flux to the solar wind. If these non-equilibrium features are sufficiently strong, they drive kinetic micro-instabilities. We develop a semi-graphical framework based on the equations of quasi-linear theory to describe electron-driven instabilities in the solar wind. We apply our framework to resonant instabilities driven by temperature anisotropies. These include the electron whistler anisotropy instability and the propagating electron firehose instability. We then describe resonant instabilities driven by reflectional asymmetries in the electron distribution function. These include the electron/ion-acoustic, kinetic Alfv\'en heat-flux, Langmuir, electron-beam, electron/ion-cyclotron, electron/electron-acoustic, whistler heat-flux, oblique fast-magnetosonic/whistler, lower-hybrid fan, and electron-deficit whistler instability. We briefly comment on non-resonant instabilities driven by electron temperature anisotropies such as the mirror-mode and the non-propagating firehose instability. We conclude our review with a list of open research topics in the field of electron-driven instabilities in the solar wind., Comment: Accepted for publication in Frontiers in Astronomy and Space Sciences. 47 pages, 11 figures

Published

2022

14. Radial evolution of thermal and suprathermal electron populations in the slow solar wind from 0.13 to 0.5 au : Parker Solar Probe Observations

Author

Abraham, Joel B., Owen, Christopher J, Verscharen, Daniel, Bakrania, Mayur, Stansby, David, Wicks, Robert T., Nicolaou, Georgios, Whittlesey, Phyllis L, Rueda, Jefferson A. Agudelo, Jeong, Seong-Yeop, and Bercic, Laura

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics, Physics - Plasma Physics, Physics - Space Physics

Abstract

We develop and apply a bespoke fitting routine to a large volume of solar wind electron distribution data measured by Parker Solar Probe (PSP) over its first five orbits, covering radial distances from 0.13 to 0.5 au. We characterise the radial evolution of the electron core, halo and strahl populations in the slow solar wind during these orbits. The fractional densities of these three electron populations provide evidence for the growth of the combined suprathermal halo and strahl populations from 0.13 to 0.17 au. Moreover, the growth in the halo population is not matched by a decrease of the strahl population at these distances, as has been reported for previous observations at distances greater than 0.3 au. We also find that the halo is negligible at small heliocentric distances. The fractional strahl density remains relatively constant ~1 % below 0.2 au, suggesting that the rise in the relative halo density is not solely due to the transfer of strahl electrons into the halo., Comment: Published in ApJ

Published

2022

15. Exploring the Solar Wind from its Source on the Corona into the Inner Heliosphere during the First Solar Orbiter - Parker Solar Probe Quadrature

Author

Telloni, Daniele, Andretta, Vincenzo, Antonucci, Ester, Bemporad, Alessandro, Capuano, Giuseppe E., Fineschi, Silvano, Giordano, Silvio, Habbal, Shadia, Perrone, Denise, Pinto, Rui F., Sorriso-Valvo, Luca, Spadaro, Daniele, Susino, Roberto, Woodham, Lloyd D., Zank, Gary P., Romoli, Marco, Bale, Stuart D., Kasper, Justin C., Auchère, Frédéric, Bruno, Roberto, Capobianco, Gerardo, Case, Anthony W., Casini, Chiara, Casti, Marta, Chioetto, Paolo, Corso, Alain J., Da Deppo, Vania, De Leo, Yara, de Wit, Thierry Dudok, Frassati, Federica, Frassetto, Fabio, Goetz, Keith, Guglielmino, Salvo L., Harvey, Peter R., Heinzel, Petr, Jerse, Giovanna, Korreck, Kelly E., Landini, Federico, Larson, Davin, Liberatore, Alessandro, Livi, Roberto, MacDowall, Robert J., Magli, Enrico, Malaspina, David M., Massone, Giuseppe, Messerotti, Mauro, Moses, John D., Naletto, Giampiero, Nicolini, Gianalfredo, Nisticò, Giuseppe, Panasenco, Olga, Pancrazzi, Maurizio, Pelizzo, Maria G., Pulupa, Marc, Reale, Fabio, Romano, Paolo, Sasso, Clementina, Schühle, Udo, Stangalini, Marco, Stevens, Michael L., Strachan, Leonard, Straus, Thomas, Teriaca, Luca, Uslenghi, Michela, Velli, Marco, Verscharen, Daniel, Volpicelli, Cosimo A., Whittlesey, Phyllis, Zangrilli, Luca, Zimbardo, Gaetano, and Zuppella, Paola

Subjects

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

Abstract

This Letter addresses the first Solar Orbiter (SO) -- Parker Solar Probe (PSP) quadrature, occurring on January 18, 2021, to investigate the evolution of solar wind from the extended corona to the inner heliosphere. Assuming ballistic propagation, the same plasma volume observed remotely in corona at altitudes between 3.5 and 6.3 solar radii above the solar limb with the Metis coronagraph on SO can be tracked to PSP, orbiting at 0.1 au, thus allowing the local properties of the solar wind to be linked to the coronal source region from where it originated. Thanks to the close approach of PSP to the Sun and the simultaneous Metis observation of the solar corona, the flow-aligned magnetic field and the bulk kinetic energy flux density can be empirically inferred along the coronal current sheet with an unprecedented accuracy, allowing in particular estimation of the Alfv\'en radius at 8.7 solar radii during the time of this event. This is thus the very first study of the same solar wind plasma as it expands from the sub-Alfv\'enic solar corona to just above the Alfv\'en surface., Comment: 10 pages, 4 figures

Published

2021

16. Characteristic scales of magnetic switchback patches near the Sun and their possible association with solar supergranulation and granulation

Author

Fargette, Naïs, Lavraud, Benoit, Rouillard, Alexis, Réville, Victor, De Wit, Thierry Dudok, Froment, Clara, Halekas, Jasper S., Phan, Tai, Malaspina, David, Bale, Stuart D., Kasper, Justin, Louarn, Philippe, Case, Anthony W., Korreck, Kelly E., Larson, Davin E., Pulupa, Marc, Stevens, Michael L., Whittlesey, Phyllis L., and Berthomier, Matthieu

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Parker Solar Probe (PSP) data recorded within a heliocentric radial distance of 0.3 AU have revealed a magnetic field dominated by Alfv\'enic structures that undergo large local variations or even reversals of the radial magnetic field. They are called magnetic switchbacks, they are consistent with folds in magnetic field lines within a same magnetic sector, and are associated with velocity spikes during an otherwise calmer background. They are thought to originate either in the low solar atmosphere through magnetic reconnection processes, or result from the evolution of turbulence or velocity shears in the expanding solar wind. In this work, we investigate the temporal and spatial characteristic scales of magnetic switchback patches. We define switchbacks as a deviation from the nominal Parker spiral direction and detect them automatically for PSP encounters 1, 2, 4 and 5. We focus in particular on a 5.1-day interval dominated by switchbacks during E5. We perform a wavelet transform of the solid angle between the magnetic field and the Parker spiral and find periodic spatial modulations with two distinct wavelengths, respectively consistent with solar granulation and supergranulation scales. In addition we find that switchback occurrence and spectral properties seem to depend on the source region of the solar wind rather than on the radial distance of PSP. These results suggest that switchbacks are formed in the low corona and modulated by the solar surface convection pattern., Comment: 12 pages, 7 figures

Published

2021

17. Ambipolar electric field and potential in the solar wind estimated from electron velocity distribution functions

Author

Bercic, Laura, Maksimovic, Milan, Halekas, Jasper S., Landi, Smone, Owen, Christopher J., Verscharen, Daniel, Larson, Davin, Whittlesey, Phyllis, Badman, Samuel T., Bale, Stuart. D., Case, Anthony W., Goetz, Keith, Harvey, Peter R., Kasper, Justin C., Korreck, Kelly E., Livi, Roberto, MacDowall, Robert J., Malaspina, David M., Pulupa, Marc, and Stevens, Michael L.

Subjects

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

Abstract

The solar wind escapes from the solar corona and is accelerated, over a short distance, to its terminal velocity. The energy balance associated with this acceleration remains poorly understood. To quantify the global electrostatic contribution to the solar wind dynamics, we empirically estimate the ambipolar electric field ($\mathrm{E}_\parallel$) and potential ($\Phi_\mathrm{r,\infty}$). We analyse electron velocity distribution functions (VDFs) measured in the near-Sun solar wind, between 20.3\,$R_S$ and 85.3\,$R_S$, by the Parker Solar Probe. We test the predictions of two different solar wind models. Close to the Sun, the VDFs exhibit a suprathermal electron deficit in the sunward, magnetic field aligned part of phase space. We argue that the sunward deficit is a remnant of the electron cutoff predicted by collisionless exospheric models (Lemaire & Sherer 1970, 1971, Jockers 1970). This cutoff energy is directly linked to $\Phi_\mathrm{r,\infty}$. Competing effects of $\mathrm{E}_\parallel$ and Coulomb collisions in the solar wind are addressed by the Steady Electron Runaway Model (SERM) (Scudder 2019). In this model, electron phase space is separated into collisionally overdamped and underdamped regions. We assume that this boundary velocity at small pitch angles coincides with the strahl break-point energy, which allows us to calculate $\mathrm{E}_\parallel$. The obtained $\Phi_\mathrm{r,\infty}$ and $\mathrm{E}_\parallel$ agree well with theoretical expectations. They decrease with radial distance as power law functions with indices $\alpha_\Phi = -0.66$ and $\alpha_\mathrm{E} = -1.69$. We finally estimate the velocity gained by protons from electrostatic acceleration, which equals to 77\% calculated from the exospheric models, and to 44\% from the SERM model.

Published

2021

18. Alfv\'enic versus non-Alfv\'enic turbulence in the inner heliosphere as observed by Parker Solar Probe

Author

Shi, Chen, Velli, Marco, Panasenco, Olga, Tenerani, Anna, Réville, Victor, Bale, Stuart D., Kasper, Justin, Korreck, Kelly, Bonnell, J. W., de Wit, Thierry Dudok, Malaspina, David M., Goetz, Keith, Harvey, Peter R., MacDowall, Robert J., Pulupa, Marc, Case, Anthony W., Larson, Davin, Verniero, J. L., Livi, Roberto, Stevens, Michael, Whittlesey, Phyllis, Maksimovic, Milan, and Moncuquet, Michel

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

We make use of the Parker Solar Probe (PSP) data to explore the nature of solar wind turbulence focusing on the Alfv\'enic character and power spectra of the fluctuations and their dependence on distance and context (i.e. large scale solar wind properties), aiming to understand the role that different effects such as source properties, solar wind expansion, stream interaction might play in determining the turbulent state. We carry out a statistical survey of the data from the first five orbits of PSP with a focus on how the fluctuation properties at the large, MHD scales, vary with different solar wind streams and distance from the Sun. A more in-depth analysis from several selected periods is also presented. Our results show that as fluctuations are transported outward by the solar wind, the magnetic field spectrum steepens while the shape of the velocity spectrum remains unchanged. The steepening process is controlled by the "age" of the turbulence, determined by the wind speed together with the radial distance. Statistically, faster solar wind has higher "Alfv\'enicity", with more dominant outward propagating wave component and more balanced magnetic/kinetic energies. The outward wave dominance gradually weakens with radial distance, while the excess of magnetic energy is found to be stronger as we move closer toward the Sun. We show that the turbulence properties can vary significantly stream to stream even if these streams are of similar speed, indicating very different origins of these streams. Especially, the slow wind that originates near the polar coronal holes has much lower Alfv\'enicity compared with the slow wind that originates from the active regions/pseudostreamers. We show that structures such as heliospheric current sheets and velocity shears can play an important role in modifying the properties of the turbulence.

Published

2021

19. The Contribution of Alpha Particles to the Solar Wind Angular Momentum Flux in the Inner Heliosphere

Author

Finley, Adam J., McManus, Michael D., Matt, Sean P., Kasper, Justin C., Korreck, Kelly E., Case, Anthony W., Stevens, Michael L., Whittlesey, Phyllis, Larson, Davin, Livi, Roberto, Bale, Stuart D., de Wit, Thierry Dudok, Goetz, Keith, Harvey, Peter R., MacDowall, Robert J., Malaspina, David M., and Pulupa, Marc

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

An accurate assessment of the Sun's angular momentum (AM) loss rate is an independent constraint for models that describe the rotation evolution of Sun-like stars. In-situ measurements of the solar wind taken by Parker Solar Probe (PSP), at radial distances of $\sim 28-55R_{\odot}$, are used to constrain the solar wind AM-loss rate. For the first time with PSP, this includes a measurement of the alpha particle contribution. The mechanical AM flux in the solar wind protons (core and beam), and alpha particles, is determined as well as the transport of AM through stresses in the interplanetary magnetic field. The solar wind AM flux is averaged over three hour increments, so that our findings more accurately represent the bulk flow. During the third and fourth perihelion passes of PSP, the alpha particles contain around a fifth of the mechanical AM flux in the solar wind (the rest is carried by the protons). The proton beam is found to contain $\sim 10-50\%$ of the proton AM flux. The sign of the alpha particle AM flux is observed to correlate with the proton core. The slow wind has a positive AM flux (removing AM from the Sun as expected), and the fast wind has a negative AM flux. As with previous works, the differential velocity between the alpha particles and the proton core tends to be aligned with the interplanetary magnetic field. In future, by utilising the trends in the alpha-proton differential velocity, it may be possible to estimate the alpha particle contribution when only measurements of the proton core are available. Based on the observations from this work, the alpha particles contribute an additional $10-20\%$ to estimates of the solar wind AM-loss rate which consider only the proton and magnetic field contributions. Additionally, the AM flux of the proton beam can be just as significant as the alpha particles, and so should not be neglected in future studies., Comment: 12 pages + 8 figures, accepted for publication in A&A

Published

2020

20. Wave-particle energy transfer directly observed in an ion cyclotron wave

Author

Vech, Daniel, Martinovic, Mihailo M., Klein, Kristopher G., Malaspina, David M., Bowen, Trevor A., Verniero, Jenny L., Paulson, Kristoff, de Wit, Thierry Dudok, Kasper, Justin C., Huang, Jia, Stevens, Michael L., Case, Anthony W., Korreck, Kelly, Mozer, Forrest S., Goodrich, Katherine A., Bale, Stuart D., Whittlesey, Phyllis L., Livi, Roberto, Larson, Davin E., Pulupa, Marc, Bonnell, John, Harvey, Peter, Goetz, Keith, and MacDowall, Robert

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

Context. The first studies with Parker Solar Probe (PSP) data have made significant progress toward the understanding of the fundamental properties of ion cyclotron waves in the inner heliosphere. The survey mode particle measurements of PSP, however, did not make it possible to measure the coupling between electromagnetic fields and particles on the time scale of the wave periods. Aims. We present a novel approach to study wave-particle energy exchange with PSP. Methods. We use the Flux Angle operation mode of the Solar Probe Cup in conjunction with the electric field measurements and present a case study when the Flux Angle mode measured the direct interaction of the proton velocity distribution with an ion cyclotron wave. Results. Our results suggest that the energy transfer from fields to particles on the timescale of a cyclotron period is equal to approximately 3-6% of the electromagnetic energy flux. This rate is consistent with the hypothesis that the ion cyclotron wave was locally generated in the solar wind., Comment: Accepted in Astronomy and Astrophysics

Published

2020

21. The Solar Wind Angular Momentum Flux as Observed by Parker Solar Probe

Author

Finley, Adam J., Matt, Sean P., Réville, Victor, Pinto, Rui F., Owens, Mathew, Kasper, Justin C., Korreck, Kelly E., Case, A. W., Stevens, Michael L., Whittlesey, Phyllis, Larson, Davin, and Livi, Roberto

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics

Abstract

The long-term evolution of the Sun's rotation period cannot be directly observed, and is instead inferred from trends in the measured rotation periods of other Sun-like stars. Assuming the Sun spins-down as it ages, following rotation rate $\propto$ age$^{-1/2}$, requires the current solar angular momentum-loss rate to be around $6\times 10^{30}$erg. Magnetohydrodynamic models, and previous observations of the solar wind (from the Helios and Wind spacecraft), generally predict a values closer to $1\times 10^{30}$erg or $3\times 10^{30}$erg, respectively. Recently, the Parker Solar Probe (PSP) observed tangential solar wind speeds as high as $\sim50$km/s in a localized region of the inner heliosphere. If such rotational flows were prevalent throughout the corona, it would imply that the solar wind angular momentum-loss rate is an order of magnitude larger than all of those previous estimations. In this letter, we evaluate the angular momentum flux in the solar wind, using data from the first two orbits of PSP. The solar wind is observed to contain both large positive (as seen during perihelion), and negative angular momentum fluxes. We analyse two solar wind streams that were repeatedly traversed by PSP; the first is a slow wind stream whose average angular momentum flux fluctuates between positive to negative, and the second is an intermediate speed stream containing a positive angular momentum flux (more consistent with a constant flow of angular momentum). When the data from PSP is evaluated holistically, the average equatorial angular momentum flux implies a global angular momentum-loss rate of around $2.6-4.2\times 10^{30}$ erg (which is more consistent with observations from previous spacecraft)., Comment: 11 pages + 6 figures, accepted for publication to ApJL

Published

2020

22. Small-scale Magnetic Flux Ropes in the First two Parker Solar Probe Encounters

Author

Chen, Yu, Hu, Qiang, Zhao, Lingling, Kasper, Justin C., Bale, Stuart D., Korreck, Kelly E., Case, Anthony W., Stevens, Michael L., Bonnell, John W., Goetz, Keith, Harvey, Peter R., Klein, Kristopher G., Larson, Davin E., Livi, Roberto, MacDowall, Robert J., Malaspina, David M., Pulupa, Marc, and Whittlesey, Phyllis L.

Subjects

Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics

Abstract

Small-scale magnetic flux ropes (SFRs) are a type of structures in the solar wind that possess helical magnetic field lines. In a recent report (Chen & Hu 2020), we presented the radial variations of the properties of SFR from 0.29 to 8 au using in situ measurements from the Helios, ACE/Wind, Ulysses, and Voyager spacecraft. With the launch of the Parker Solar Probe (PSP), we extend our previous investigation further into the inner heliosphere. We apply a Grad-Shafranov-based algorithm to identify SFRs during the first two PSP encounters. We find that the number of SFRs detected near the Sun is much less than that at larger radial distances, where magnetohydrodynamic (MHD) turbulence may act as the local source to produce these structures. The prevalence of Alfvenic structures significantly suppresses the detection of SFRs at closer distances. We compare the SFR event list with other event identification methods, yielding a dozen well-matched events. The cross-section maps of two selected events confirm the cylindrical magnetic flux rope configuration. The power-law relation between the SFR magnetic field and heliocentric distances seems to hold down to 0.16 au., Comment: Accepted by ApJ on 2020 Sep 10

Published

2020

23. Coronal Electron Temperature inferred from the Strahl Electrons in the Inner Heliosphere: Parker Solar Probe and Helios observations

Author

Bercic, Laura, Larson, Davin, Whittlesey, Phyllis, Maksimovic, Milan, Badman, Samuel T., Landi, Simone, Matteini, Lorenzo, Bale, Stuart. D., Bonnell, John W., Case, Anthony W., de Wit, Thierry Dudok, Goetz, Keith, Harvey, Peter R., Kasper, Justin C., Korreck, Kelly E., Livi, Roberto, MacDowall, Robert J., Malaspina, David M., Pulupa, Marc, and Stevens, Michael L.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

The shape of the electron velocity distribution function plays an important role in the dynamics of the solar wind acceleration. Electrons are normally modelled with three components, the core, the halo, and the strahl. We investigate how well the fast strahl electrons in the inner heliosphere preserve the information about the coronal electron temperature at their origin. We analysed the data obtained by two missions, Helios spanning the distances between 65 and 215 R$_S$, and Parker Solar Probe (PSP) reaching down to 35 R$_S$ during its first two orbits around the Sun. The electron strahl was characterised with two parameters, pitch-angle width (PAW), and the strahl parallel temperature (T$_{s\parallel}$). PSP observations confirm the already reported dependence of strahl PAW on core parallel plasma beta ($\beta_{ec\parallel}$)\citep{Bercic2019}. Most of the strahl measured by PSP appear narrow with PAW reaching down to 30$^o$. The portion of the strahl velocity distribution function aligned with the magnetic field is for the measured energy range well described by a Maxwellian distribution function. T$_{s\parallel}$ was found to be anti-correlated with the solar wind velocity, and independent of radial distance. These observations imply that T$_{s\parallel}$ carries the information about the coronal electron temperature. The obtained values are in agreement with coronal temperatures measured using spectroscopy (David et al. 2998), and the inferred solar wind source regions during the first orbit of PSP agree with the predictions using a PFSS model (Bale et al. 2019, Badman et al. 2019).

Published

2020

24. The Solar Probe ANalyzers -- Electrons on Parker Solar Probe

Author

Whittlesey, Phyllis L, Larson, Davin E, Kasper, Justin C, Halekas, Jasper, Abatcha, Mamuda, Abiad, Robert, Berthomier, M., Case, A. W., Chen, Jianxin, Curtis, David W, Dalton, Gregory, Klein, Kristopher G, Korreck, Kelly E, Livi, Roberto, Ludlam, Michael, Marckwordt, Mario, Rahmati, Ali, Robinson, Miles, Slagle, Amanda, Stevens, M L, Tiu, Chris, and Verniero, J L

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Electrostatic analyzers of different designs have been used since the earliest days of the space age, beginning with the very earliest solar wind measurements made by Mariner 2 en route to Venus in 1962. The Parker Solar Probe (PSP) mission, NASA's first dedicated mission to study the innermost reaches of the heliosphere, makes its thermal plasma measurements using a suite of instruments called the Solar Wind Electrons, Alphas, and Protons (SWEAP) investigation. SWEAP's electron Parker Solar Probe Analyzer (SPAN-E) instruments are a pair of top-hat electrostatic analyzers on PSP that are capable of measuring the electron distribution function in the solar wind from 2 eV to 30 keV. For the first time, in-situ measurements of thermal electrons provided by SPAN-E will help reveal the heating and acceleration mechanisms driving the evolution of the solar wind at the points of acceleration and heating, closer than ever before to the Sun. This paper details the design of the SPAN-E sensors and their operation, data formats, and measurement caveats from Parker Solar Probe's first two close encounters with the Sun., Comment: This draft has been Accepted in the Astrophysical Journal Special issue for Parker Solar Probe

Published

2020

25. The Radial Dependence of Proton-scale Magnetic Spectral Break in Slow Solar Wind during PSP Encounter 2

Author

Duan, Die, Bowen, Trevor A., Chen, Christopher H. K., Mallet, Alfred, He, Jiansen, Bale, Stuart D., Vech, Daniel, Kasper, J. C., Pulupa, Marc, Bonnell, John W., Case, Anthony W., de Wit, Thierry Dudok, Goetz, Keith, Harvey, Peter R., Korreck, Kelly E., Larson, Davin, Livi, Roberto, MacDowall, Robert J., Malaspina, David M., Stevens, Michael, and Whittlesey, Phyllis

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

Magnetic field fluctuations in the solar wind are commonly observed to follow a power law spectrum. Near proton-kinetic scales, a spectral break occurs which is commonly interpreted as a transition to kinetic turbulence. However, this transition is not yet entirely understood. By studying the scaling of the break with various plasma properties, it may be possible to constrain the processes leading to the onset of kinetic turbulence. Using data from Parker Solar Probe (\textit{PSP}), we measure the proton scale break over a range of heliocentric distances, enabling a measurement of the transition from inertial to kinetic scale turbulence under various plasma conditions. We find that the break frequency $f_b$ increases as the heliocentric distance $r$ decreases in the slow solar wind following a power law $f_b\sim r^{-1.11}$. We also compare this to the characteristic plasma ion scales to relate the break to the possible physical mechanisms occurring at this scale. The ratio between $f_b$ and $f_c$, the Doppler shifted ion cyclotron resonance scale, is approximately unity for all plasma $\beta_p$. At high $\beta_p$ the ratio between $f_b$ and $f_\rho$, the Doppler shifted gyroscale, is approximately unity; while at low $\beta_p$ the ratio between $f_b$ and $f_d$, the Doppler shifted proton-inertial length is unity. Due to the large comparable Alfv\'en and solar wind speeds, we analyze these results using both the standard and modified Taylor hypothesis, demonstrating robust statistical results., Comment: Accepted by ApJS, Dec 14, 2019

Published

2020

26. Inner-Heliosphere Signatures of Ion-Scale Dissipation and Nonlinear Interaction

Author

Bowen, Trevor A., Mallet, Alfred, Bale, Stuart D., Bonnell, J. W., Case, Anthony W., Chandran, Benjamin D. G., Chasapis, Alexandros, Chen, Christopher H. K., Duan, Die, de Wit, Thierry Dudok, Goetz, Keith, Halekas, Jasper, Harvey, Peter R., Kasper, J. C., Korreck, Kelly E., Larson, Davin, Livi, Roberto, MacDowall, Robert J., Malaspina, David M., Pulupa, Marc, Stevens, Michael, and Whittlesey, Phyllis

Subjects

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

Abstract

We perform a statistical study of the turbulent power spectrum at inertial and kinetic scales observed during the first perihelion encounter of Parker Solar Probe. We find that often there is an extremely steep scaling range of the power spectrum just above the ion-kinetic scales, similar to prior observations at 1 AU, with a power-law index of around $-4$. Based on our measurements, we demonstrate that either a significant ($>50\%$) fraction of the total turbulent energy flux is dissipated in this range of scales, or the characteristic nonlinear interaction time of the turbulence decreases dramatically from the expectation based solely on the dispersive nature of nonlinearly interacting kinetic Alfv\'en waves.

Published

2020

27. Density Fluctuations in the Solar Wind Based on Type III Radio Bursts Observed by Parker Solar Probe

Author

Krupar, Vratislav, Szabo, Adam, Maksimovic, Milan, Kruparova, Oksana, Kontar, Eduard P., Balmaceda, Laura A., Bonnin, Xavier, Bale, Stuart D., Pulupa, Marc, Malaspina, David M., Bonnell, John W., Harvey, Peter R., Goetz, Keith, de Wit, Thierry Dudok, MacDowall, Robert J., Kasper, Justin C., Case, Anthony W., Korreck, Kelly E., Larson, Davin E., Livi, Roberto, Stevens, Michael L., Whittlesey, Phyllis L., and Hegedus, Alexander M.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Earth and Planetary Astrophysics, Physics - Plasma Physics, Physics - Space Physics

Abstract

Radio waves are strongly scattered in the solar wind, so that their apparent sources seem to be considerably larger and shifted than the actual ones. Since the scattering depends on the spectrum of density turbulence, better understanding of the radio wave propagation provides indirect information on the relative density fluctuations $\epsilon=\langle\delta n\rangle/\langle n\rangle$ at the effective turbulence scale length. Here, we have analyzed 30 type III bursts detected by Parker Solar Probe (PSP). For the first time, we have retrieved type III burst decay times $\tau_{\rm{d}}$ between 1 MHz and 10 MHz thanks to an unparalleled temporal resolution of PSP. We observed a significant deviation in a power-law slope for frequencies above 1 MHz when compared to previous measurements below 1 MHz by the twin-spacecraft Solar TErrestrial RElations Observatory (STEREO) mission. We note that altitudes of radio bursts generated at 1 MHz roughly coincide with an expected location of the Alfv\'{e}n point, where the solar wind becomes super-Alfv\'{e}nic. By comparing PSP observations and Monte Carlo simulations, we predict relative density fluctuations $\epsilon$ at the effective turbulence scale length at radial distances between 2.5$R_\odot$ and 14$R_\odot$ to range from $0.22$ and $0.09$. Finally, we calculated relative density fluctuations $\epsilon$ measured in situ by PSP at a radial distance from the Sun of $35.7$~$R_\odot$ during the perihelion \#1, and the perihelion \#2 to be $0.07$ and $0.06$, respectively. It is in a very good agreement with previous STEREO predictions ($\epsilon=0.06-0.07$) obtained by remote measurements of radio sources generated at this radial distance., Comment: 12 pages, 10 figures, accepted for publication in ApJS

Published

2020

28. Relating streamer flows to density and magnetic structures at the Parker Solar Probe

Author

Rouillard, Alexis P., Kouloumvakos, Athanasios, Vourlidas, Angelos, Kasper, Justin, Bale, Stuart, Raouafi, Nour-Edine, Lavraud, Benoit, Howard, Russell A., Stenborg, Guillermo, Stevens, Michael, Poirier, Nicolas, Davies, Jackie A., Hess, Phillip, Higginson, Aleida K., Lavarra, Michael, Viall, Nicholeen M., Korreck, Kelly, Pinto, Rui F., Griton, Léa, Réville, Victor, Louarn, Philippe, Wu, Yihong, Dalmasse, Kévin, Génot, Vincent, Case, Anthony W., Whittlesey, Phyllis, Larson, Davin, Halekas, Jasper S., Livi, Roberto, Goetz, Keith, Harvey, Peter R., MacDowall, Robert J., Malaspina, David, Pulupa, Marc, Bonnell, John, de Witt, Thierry Dudok, and Penou, Emmanuel

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

The physical mechanisms that produce the slow solar wind are still highly debated. Parker Solar Probe's (PSP's) second solar encounter provided a new opportunity to relate in situ measurements of the nascent slow solar wind with white-light images of streamer flows. We exploit data taken by the Solar and Heliospheric Observatory (SOHO), the Solar TErrestrial RElations Observatory (STEREO) and the Wide Imager on Solar Probe to reveal for the first time a close link between imaged streamer flows and the high-density plasma measured by the Solar Wind Electrons Alphas and Protons (SWEAP) experiment. We identify different types of slow winds measured by PSP that we relate to the spacecraft's magnetic connectivity (or not) to streamer flows. SWEAP measured high-density and highly variable plasma when PSP was well connected to streamers but more tenuous wind with much weaker density variations when it exited streamer flows. STEREO imaging of the release and propagation of small transients from the Sun to PSP reveals that the spacecraft was continually impacted by the southern edge of streamer transients. The impact of specific density structures is marked by a higher occurrence of magnetic field reversals measured by the FIELDS magnetometers. Magnetic reversals originating from the streamers are associated with larger density variations compared with reversals originating outside streamers. We tentatively interpret these findings in terms of magnetic reconnection between open magnetic fields and coronal loops with different properties, providing support for the formation of a subset of the slow wind by magnetic reconnection., Comment: 15 pages, 8 figures, to appear in the Parker Solar Probe ApJ Special Issue

Published

2020

29. Cross Helicity Reversals In Magnetic Switchbacks

Author

McManus, Michael D., Bowen, Trevor A., Mallet, Alfred, Chen, Christopher H. K., Chandran, Benjamin D. G., Bale, Stuart D., Larson, Davin E., de Wit, Thierry Dudok, Kasper, Justin C., Stevens, Michael, Whittlesey, Phyllis, Livi, Roberto, Korreck, Kelly E., Goetz, Keith, Harvey, Peter R., Pulupa, Marc, MacDowall, Robert J., Malaspina, David M., Case, Anthony W., and Bonnell, John W.

Subjects

Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics

Abstract

We consider 2D joint distributions of normalised residual energy $\sigma_r(s,t)$ and cross helicity $\sigma_c(s,t)$ during one day of Parker Solar Probe's (PSP's) first encounter as a function of wavelet scale $s$. The broad features of the distributions are similar to previous observations made by HELIOS in slow solar wind, namely well correlated and fairly Alfv\'enic, except for a population with negative cross helicity which is seen at shorter wavelet scales. We show that this population is due to the presence of magnetic switchbacks, brief periods where the magnetic field polarity reverses. Such switchbacks have been observed before, both in HELIOS data and in Ulysses data in the polar solar wind. Their abundance and short timescales as seen by PSP in its first encounter is a new observation, and their precise origin is still unknown. By analysing these MHD invariants as a function of wavelet scale we show that MHD waves do indeed follow the local mean magnetic field through switchbacks, with net Elsasser flux propagating inward during the field reversal, and that they therefore must be local kinks in the magnetic field and not due to small regions of opposite polarity on the surface of the Sun. Such observations are important to keep in mind as computing cross helicity without taking into account the effect of switchbacks may result in spurious underestimation of $\sigma_c$ as PSP gets closer to the Sun in later orbits.

Published

2019

30. Energetic Particle Increases Associated with Stream Interaction Regions

Author

Cohen, C. M. S., Christian, E. R., Cummings, A. C., Davis, A. J., Desai, M. I., Giacalone, J., Hill, M. E., Joyce, C. J., Labrador, A. W., Leske, R. A., Matthaeus, W. H., McComas, D. J., McNutt, Jr., R. L., Mewaldt, R. A., Mitchell, D. G., Rankin, J. S., Roelof, E. C., Schwadron, N. A., Stone, E. C., Szalay, J. R., Wiedenbeck, M. E., Allen, R. C., Ho, G. C., Jian, L. K., Lario, D., Odstrcil, D., Bale, S. D., Badman, S. T., Pulupa, M., MacDowall, R. J., Kasper, J. C., Case, A. W., Korreck, K. E., Larson, D. E., Livi, Roberto, Stevens, M. L., and Whittlesey, Phyllis

Subjects

Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics

Abstract

The Parker Solar Probe was launched on 2018 August 12 and completed its second orbit on 2019 June 19 with perihelion of 35.7 solar radii. During this time, the Energetic particle Instrument-Hi (EPI-Hi, one of the two energetic particle instruments comprising the Integrated Science Investigation of the Sun, ISOIS) measured seven proton intensity increases associated with stream interaction regions (SIRs), two of which appear to be occurring in the same region corotating with the Sun. The events are relatively weak, with observed proton spectra extending to only a few MeV and lasting for a few days. The proton spectra are best characterized by power laws with indices ranging from -4.3 to -6.5, generally softer than events associated with SIRs observed at 1 au and beyond. Helium spectra were also obtained with similar indices, allowing He/H abundance ratios to be calculated for each event. We find values of 0.016-0.031, which are consistent with ratios obtained previously for corotating interaction region events with fast solar wind < 600 km s-1. Using the observed solar wind data combined with solar wind simulations, we study the solar wind structures associated with these events and identify additional spacecraft near 1 au appropriately positioned to observe the same structures after some corotation. Examination of the energetic particle observations from these spacecraft yields two events that may correspond to the energetic particle increases seen by EPI-Hi earlier.

Published

2019

31. Kinetic Scale Spectral Features of Cross Helicity and Residual Energy in the Inner Heliosphere

Author

Vech, Daniel, Kasper, Justin C., Klein, Kristopher G., Huang, Jia, Stevens, Michael L., Chen, Christopher H. K., Case, Anthony W., Korreck, Kelly, Bale, Stuart D., Bowen, Trevor A., Whittlesey, Phyllis L., Livi, Roberto, Larson, Davin E., Malaspina, David, Pulupa, Marc, Bonnell, John, Harvey, Peter, Goetz, Keith, de Wit, Thierry Dudok, and MacDowall, Robert

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

In this Paper, we present the first results from the Flux Angle operation mode of the Faraday Cup instrument onboard Parker Solar Probe. The Flux Angle mode allows rapid measurements of phase space density fluctuations close to the peak of the proton velocity distribution function with a cadence of 293 Hz. This approach provides an invaluable tool for understanding kinetic scale turbulence in the solar wind and solar corona. We describe a technique to convert the phase space density fluctuations into vector velocity components and compute several turbulence parameters such as spectral index, residual energy and cross helicity during two intervals the Flux Angle mode was used in Parker Solar Probe's first encounter at 0.174 AU distance from the Sun., Comment: Accepted for publication in ApJS

Published

2019

32. Plasma Waves near the Electron Cyclotron Frequency in the near-Sun Solar Wind

Author

Malaspina, David M., Halekas, Jasper, Bercic, Laura, Larson, Davin, Whittlesey, Phyllis, Bale, Stuart D., Bonnell, John W., de Wit, Thierry Dudok, Ergun, Robert E., Howes, Gregory, Goetz, Keith, Goodrich, Katherine, Harvey, Peter R., MacDowall, Robert J., Pulupa, Marc, Case, Anthony W., Kasper, Justin C., Korreck, Kelly E., Livi, Roberto, and Stevens, Michael L.

Subjects

Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics

Abstract

Data from the first two orbits of the Sun by Parker Solar Probe reveal that the solar wind sunward of 50 solar radii is replete with plasma waves and instabilities. One of the most prominent plasma wave power enhancements in this region appears near the electron cyclotron frequency (f_ce). Most of this wave power is concentrated in electric field fluctuations near 0.7 f_ce and f_ce, with strong harmonics of both frequencies extending above f_ce. At least two distinct, often concurrent, wave modes are observed, preliminarily identified as electrostatic whistler-mode waves and electron Bernstein waves. Wave intervals range in duration from a few seconds to hours. Both the amplitudes and number of detections of these near-f_ce waves increase significantly with decreasing distance to the Sun, suggesting that they play an important role in the evolution of electron populations in the near-Sun solar wind. Correlations are found between the detection of these waves and properties of solar wind electron populations, including electron core drift, implying that these waves play a role in regulating the heat flux carried by solar wind electrons. Observation of these near-f_ce waves is found to be strongly correlated with near-radial solar wind magnetic field configurations with low levels of magnetic turbulence. A scenario for the growth of these waves is presented which implies that regions of low-turbulence near-radial magnetic field are a prominent feature of solar wind structure near the Sun.

Published

2019

33. Proton Temperature Anisotropy Variations in Inner Heliosphere Estimated with First Parker Solar Probe Observations

Author

Huang, Jia, Kasper, Justin C., Vech, Daniel, Klein, Kristopher G., Stevens, Michael L., Martinovic, Mihailo, Alterman, Benjamin L., Ďurovcová, Tereza, Paulson, Kristoff, Maruca, Bennett A., Qudsi, Ramiz A., Case, Anthony W., Korreck, Kelly, Jian, Lan K., Velli, Marco, Lavraud, Benoit, Hegedus, Alexander M., Bert, C. M., Holmes, J., Bale, Stuart D., Larson, Davin E., Livi, Roberto, Whittlesey, Phyllis, Pulupa, Marc, MacDowall, Robert J., Malaspina, David M., Bonnell, John W., Harvey, Peter R., goetz, Keith, and de Wit, Thierry Dudok

Subjects

Physics - Space Physics, Physics - Plasma Physics

Abstract

We report proton temperature anisotropy variations in the inner heliosphere with Parker Solar Probe (PSP) observations. Using a linear fitting method, we derive proton temperature anisotropy with temperatures measured by the Solar Probe Cup (SPC) from the SWEAP instrument suite and magnetic field observations from the FIELDS instrument suite. The observed radial dependence of temperature variations in the fast solar wind implies stronger perpendicular heating and parallel cooling than previous results from Helios measurements made at larger radial distances. The anti-correlation between proton temperature anisotropy and parallel plasma beta is retained in fast solar wind. However, the temperature anisotropies of the slow solar wind seem to be well constrained by the mirror and parallel firehose instabilities. The perpendicular heating of the slow solar wind inside 0.24 AU may contribute to its same trend up against mirror instability thresholds as fast solar wind. These results suggest that we may see stronger anisotropy heating than expected in inner heliosphere., Comment: Submit to ApJ special issue for Parker Solar Probe first results

Published

2019

34. The role of Alfv\'en wave dynamics on the large scale properties of the solar wind: comparing an MHD simulation with PSP E1 data

Author

Réville, Victor, Velli, Marco, Panasenco, Olga, Tenerani, Anna, Shi, Chen, Badman, Samuel T., Bale, Stuart D., Kasper, J. C., Stevens, Michael L., Korreck, Kelly E., Bonnell, J. W., Case, Anthony W., de Wit, Thierry Dudok, Goetz, Keith, Harvey, Peter R., Larson, Davin E., Livi, Roberto, Malaspina, David M., MacDowall, Robert J., Pulupa, Marc, and Whittlesey, Phyllis L.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

During Parker Solar Probe's first orbit, the solar wind plasma has been observed in situ closer than ever before, the perihelion on November 6th 2018 revealing a flow that is constantly permeated by large amplitude Alfv\'enic fluctuations. These include radial magnetic field reversals, or switchbacks, that seem to be a persistent feature of the young solar wind. The measurements also reveal a very strong, unexpected, azimuthal velocity component. In this work, we numerically model the solar corona during this first encounter, solving the MHD equations and accounting for Alfv\'en wave transport and dissipation. We find that the large scale plasma parameters are well reproduced, allowing the computation of the solar wind sources at Probe with confidence. We try to understand the dynamical nature of the solar wind to explain both the amplitude of the observed radial magnetic field and of the azimuthal velocities., Comment: Accepted Erratum includeded as an appendix. Updated references. 17 pages, 9 figures total

Published

2019

35. Statistics and Polarization of Type III Radio Bursts Observed in the Inner Heliosphere

Author

Pulupa, Marc, Bale, Stuart D., Badman, Samuel T., Bonnell, John W., Case, Anthony W., de Wit, Thierry Dudok, Goetz, Keith, Harvey, Peter R., Hegedus, Alexander M., Kasper, Justin C., Korreck, Kelly E., Krasnoselskikh, Vladimir, Larson, Davin, Lecacheux, Alain, Livi, Roberto, MacDowall, Robert J., Maksimovic, Milan, Malaspina, David M., Oliveros, Juan Carlos Martínez, Meyer-Vernet, Nicole, Moncuquet, Michel, Stevens, Michael, and Whittlesey, Phyllis

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

We present initial results from the Radio Frequency Spectrometer (RFS), the high frequency component of the FIELDS experiment on the Parker Solar Probe (PSP). During the first PSP solar encounter (2018 November), only a few small radio bursts were observed. During the second encounter (2019 April), copious Type III radio bursts occurred, including intervals of radio storms where bursts occurred continuously. In this paper, we present initial observations of the characteristics of Type III radio bursts in the inner heliosphere, calculating occurrence rates, amplitude distributions, and spectral properties of the observed bursts. We also report observations of several bursts during the second encounter which display circular polarization in the right hand polarized sense, with a degree of polarization of 0.15-0.38 in the range from 8-12 MHz. The degree of polarization can be explained either by depolarization of initially 100% polarized $o$-mode emission, or by direct generation of emission in the $o$ and $x$-mode simultaneously. Direct in situ observations in future PSP encounters could provide data which can distinguish these mechanisms., Comment: 12 pages, 7 figures, to be published in ApJS

Published

2019

36. Magnetic field kinks and folds in the solar wind

Author

Tenerani, Anna, Velli, Marco, Matteini, Lorenzo, Réville, Victor, Shi, Chen, Bale, Stuart D., Kasper, Justin, Bonnell, J. W., Case, Anthony W., de Wit, Thierry Dudok, Goetz, Keith, Harvey, Peter R., Klein, Kristopher G., Korreck, Kelly, Larson, Davin, Livi, Roberto, MacDowall, Robert J., Malaspina, David M., Pulupa, Marc, Stevens, Michael, and Whittlesey, Phyllis

Subjects

Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics

Abstract

Parker Solar Probe (PSP) observations during its first encounter at 35.7 $R_\odot$ have shown the presence of magnetic field lines which are strongly perturbed to the point that they produce local inversions of the radial magnetic field, known as switchbacks. Their counterparts in the solar wind velocity field are local enhancements in the radial speed, or jets, displaying (in all components) the velocity-magnetic field correlation typical of large amplitude Alfv\'en waves propagating away from the Sun. Switchbacks and radial jets have previously been observed over a wide range of heliocentric distances by Helios, WIND and Ulysses, although they were prevalent in significantly faster streams than seen at PSP. Here we study via numerical MHD simulations the evolution of such large amplitude Alfv\'enic fluctuations by including, in agreement with observations, both a radial magnetic field inversion and an initially constant total magnetic pressure. Despite the extremely large excursion of magnetic and velocity fields, switchbacks are seen to persist for up to hundreds of Alfv\'en crossing times before eventually decaying due to the parametric decay instability. Our results suggest that such switchback/jet configurations might indeed originate in the lower corona and survive out to PSP distances, provided the background solar wind is sufficiently calm, in the sense of not being pervaded by strong density fluctuations or other gradients, such as stream or magnetic field shears, that might destabilize or destroy them over shorter timescales., Comment: Accepted for publication on APJ PSP special issue

Published

2019

37. Switchbacks in the near-Sun magnetic field: long memory and impact on the turbulence cascade

Author

de Wit, Thierry Dudok, Krasnoselskikh, Vladimir V., Bale, Stuart D., Bonnell, John W., Bowen, Trevor A., Chen, Christopher H. K., Froment, Clara, Goetz, Keith, Harvey, Peter R., Jagarlamudi, Vamsee Krishna, Larosa, Andrea, MacDowall, Robert J., Malaspina, David M., Matthaeus, William H., Pulupa, Marc, Velli, Marco, and Whittlesey, Phyllis L.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

One of the most striking observations made by Parker Solar Probe during its first solar encounter is the omnipresence of rapid polarity reversals in a magnetic field that is otherwise mostly radial. These so-called switchbacks strongly affect the dynamics of the magnetic field. We concentrate here on their macroscopic properties. First, we find that these structures are self-similar, and have neither a characteristic magnitude, nor a characteristic duration. Their waiting time statistics shows evidence for aggregation. The associated long memory resides in their occurrence rate, and is not inherent to the background fluctuations. Interestingly, the spectral properties of inertial range turbulence differ inside and outside of switchback structures; in the latter the $1/f$ range extends to higher frequencies. These results suggest that outside of these structures we are in the presence of lower amplitude fluctuations with a shorter turbulent inertial range. We conjecture that these correspond to a pristine solar wind., Comment: 10 figures, to appear in The Astrophysical Journal Supplement Series (2020)

Published

2019

38. The Enhancement of Proton Stochastic Heating in the near-Sun Solar Wind

Author

Martinović, Mihailo M., Klein, Kristopher G., Kasper, Justin C., Case, Anthony W., Korreck, Kelly E., Larson, Davin, Livi, Roberto, Stevens, Michael, Whittlesey, Phyllis, Chandran, Benjamin D. G., Alterman, Ben L., Huang, Jia, Chen, Christopher H. K., Bale, Stuart D., Pulupa, Marc, Malaspina, David M., Bonnell, John W., Harvey, Peter R., Goetz, Keith, de Wit, Thierry Dudok, and MacDowall, Robert J.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics

Abstract

Stochastic heating is a non-linear heating mechanism driven by the violation of magnetic moment invariance due to large-amplitude turbulent fluctuations producing diffusion of ions towards higher kinetic energies in the direction perpendicular to the magnetic field. It is frequently invoked as a mechanism responsible for the heating of ions in the solar wind. Here, we quantify for the first time the proton stochastic heating rate $Q_\perp$ at radial distances from the Sun as close as $0.16$ au, using measurements from the first two Parker Solar Probe encounters. Our results for both the amplitude and radial trend of the heating rate, $Q_\perp \propto r^{-2.5}$, agree with previous results based on the Helios data set at heliocentric distances from 0.3 to 0.9 au. Also in agreement with previous results, $Q_\perp$ is significantly larger in the fast solar wind than in the slow solar wind. We identify the tendency in fast solar wind for cuts of the core proton velocity distribution transverse to the magnetic field to exhibit a flat-top shape. The observed distribution agrees with previous theoretical predictions for fast solar wind where stochastic heating is the dominant heating mechanism.

Published

2019

39. The Solar Probe Cup on Parker Solar Probe

Author

Case, Anthony W., Kasper, Justin C., Stevens, Michael L., Korreck, Kelly E., Paulson, Kristoff, Daigneau, Peter, Caldwell, Dave, Freeman, Mark, Henry, Thayne, Klingensmith, Brianna, Robinson, Miles, Berg, Peter, Tiu, Chris, Wright Jr., Kenneth H., Curtis, David, Ludlam, Michael, Larson, Davin, Whittlesey, Phyllis, Livi, Roberto, Klein, Kristopher G., and Martinović, Mihailo M.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics, Physics - Space Physics

Abstract

The Solar Probe Cup (SPC) is a Faraday Cup instrument onboard NASA's Parker Solar Probe (PSP) spacecraft designed to make rapid measurements of thermal coronal and solar wind plasma. The spacecraft is in a heliocentric orbit that takes it closer to the Sun than any previous spacecraft, allowing measurements to be made where the coronal and solar wind plasma is being heated and accelerated. The SPC instrument was designed to be pointed directly at the Sun at all times, allowing the solar wind (which is flowing primarily radially away from the Sun) to be measured throughout the orbit. The instrument is capable of measuring solar wind ions with an energy/charge between 100 V and 6000 V (protons with speeds from $139-1072~km~s^{-1})$. It also measures electrons with an energy between 100 V and 1500 V. SPC has been designed to have a wide dynamic range that is capable of measuring protons and alpha particles at the closest perihelion (9.86 solar radii from the center of the Sun) and out to 0.25 AU. Initial observations from the first orbit of PSP indicate that the instrument is functioning well.

Published

2019

40. Magnetic connectivity of the ecliptic plane within 0.5 AU : PFSS modeling of the first PSP encounter

Author

Badman, Samuel T., Bale, Stuart D., Oliveros, Juan C. Martinez, Panasenco, Olga, Velli, Marco, Stansby, David, Buitrago-Casas, Juan C., Reville, Victor, Bonnell, John W., Case, Anthony W., de Wit, Thierry Dudok, Goetz, Keith, Harvey, Peter R., Kasper, Justin C., Korreck, Kelly E., Larson, Davin E., Livi, Roberto, MacDowall, Robert J., Malaspina, David M., Pulupa, Marc, Stevens, Michael L., and Whittlesey, Phyllis L.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

We compare magnetic field measurements taken by the FIELDS instrument on Parker Solar Probe (PSP) during its first solar encounter to predictions obtained by Potential Field Source Surface (PFSS) modeling. Ballistic propagation is used to connect the spacecraft to the source surface. Despite the simplicity of the model, our results show striking agreement with PSPs first observations of the heliospheric magnetic field from 0.5 AU (107.5 Rs) down to 0.16 AU (35.7 Rs). Further, we show the robustness of the agreement is improved both by allowing the photospheric input to the model to vary in time, and by advecting the field from PSP down to the PFSS model domain using in situ PSP/SWEAP measurements of the solar wind speed instead of assuming it to be constant with longitude and latitude. We also explore the source surface height parameter (RSS) to the PFSS model finding that an extraordinarily low source surface height (1.3-1.5Rs) predicts observed small scale polarity inversions which are otherwise washed out with regular modeling parameters. Finally, we extract field line traces from these models. By overlaying these on EUV images we observe magnetic connectivity to various equatorial and mid-latitude coronal holes indicating plausible magnetic footpoints and offering context for future discussions of sources of the solar wind measured by PSP., Comment: 19 Pages, 8 Main Figures, 3 Appendix Figures

Published

2019

41. Turbulence Transport Modeling and First Orbit Parker Solar Probe (PSP) Observations

Author

Adhikari, Laxman, Zank, Gary P., Zhao, Lingling, Kasper, Justin C., Korreck, Kelly E., Stevens, Michael, Case, Anthony W, Whittlesey, Phyllis, Larson, Davin, Livi, Roberto, and Klein, Kristopher G.

Subjects

Physics - Space Physics

Abstract

Parker Solar Probe (PSP) achieved its first orbit perihelion on November 6, 2018, reaching a heliocentric distance of about 0.165 au (35.55 R$_\odot$). Here, we study the evolution of fully developed turbulence associated with the slow solar wind along the PSP trajectory between 35.55 R$_\odot$ and 131.64 R$_\odot$ in the outbound direction, comparing observations to a theoretical turbulence transport model. Several turbulent quantities, such as the fluctuating kinetic energy and the corresponding correlation length, the variance of density fluctuations, and the solar wind proton temperature are determined from the PSP SWEAP plasma data along its trajectory between 35.55 R$_\odot$ and 131.64 R$_\odot$. The evolution of the PSP derived turbulent quantities are compared to the numerical solutions of the nearly incompressible magnetohydrodynamic (NI MHD) turbulence transport model recently developed by Zank et al. (2017). We find reasonable agreement between the theoretical and observed results. On the basis of these comparisons, we derive other theoretical turbulent quantities, such as the energy in forward and backward propagating modes, the total turbulent energy, the normalized residual energy and cross-helicity, the fluctuating magnetic energy, and the correlation lengths corresponding to forward and backward propagating modes, the residual energy, and the fluctuating magnetic energy.

Published

2019

42. Ion Scale Electromagnetic Waves in the Inner Heliosphere

Author

Bowen, Trevor, Mallet, Alfred, Huang, Jia, Klein, Kristopher G., Malaspina, David M., Stevens, Michael L., Bale, Stuart D., Bonnell, John W., Case, Anthony W., Chandran, Benjamin D., Chaston, Christopher, Chen, Christopher H., de Wit, Thierry Dudok, Goetz, Keith, Harvey, Peter R., Howes, Gregory G., Kasper, Justin C., Korreck, Kelly, Larson, Davin E., Livi, Roberto, MacDowall, Robert J., McManus, Michael, Pulupa, Marc, Verniero, J, and Whittlesey, Phyllis

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Understanding the physical processes in the solar wind and corona which actively contribute to heating, acceleration, and dissipation is a primary objective of NASA's Parker Solar Probe (PSP) mission. Observations of coherent electromagnetic waves at ion scales suggests that linear cyclotron resonance and non-linear processes are dynamically relevant in the inner heliosphere. A wavelet-based statistical study of coherent waves in the first perihelion encounter of PSP demonstrates the presence of transverse electromagnetic waves at ion resonant scales which are observed in 30-50\% of radial field intervals. Average wave amplitudes of approximately 4 nT are measured, while the mean duration of wave events is of order 20 seconds; however long duration wave events can exist without interruption on hour-long timescales. Though ion scale waves are preferentially observed during intervals with a radial mean magnetic field, we show that measurement constraints, associated with single spacecraft sampling of quasi-parallel waves superposed with anisotropic turbulence, render the measured quasi-parallel ion-wave spectrum unobservable when the mean magnetic field is oblique to the solar wind flow; these results imply that the occurrence of coherent ion-scale waves is not limited to a radial field configuration. The lack of strong radial scaling of characteristic wave amplitudes and duration suggests that the waves are generated {\em{in-situ}} through plasma instabilities. Additionally, observations of proton distribution functions indicate that temperature anisotropy may drive the observed ion-scale waves.

Published

2019

43. [Plasma 2020 Decadal] The essential role of multi-point measurements in turbulence investigations: the solar wind beyond single scale and beyond the Taylor Hypothesis

Author

Matthaeus, W. H., Bandyopadhyay, R., Brown, M. R., Borovsky, J., Carbone, V., Caprioli, D., Chasapis, A., Chhiber, R., Dasso, S., Dmitruk, P., Del Zanna, L., Dmitruk, P. A., Franci, Luca, Gary, S. P., Goldstein, M. L., Gomez, D., Greco, A., Horbury, T. S., Ji, Hantao, Kasper, J. C., Klein, K. G., Landi, S., Li, Hui, Malara, F., Maruca, B. A., Mininni, P., Oughton, Sean, Papini, E., Parashar, T. N., Petrosyan, Arakel, Pouquet, Annick, Retino, A., Roberts, Owen, Ruffolo, David, Servidio, Sergio, Spence, Harlan, Smith, C. W., Stawarz, J. E., TenBarge, Jason, Vasquez1, B. J., Vaivads, Andris, Valentini, F., Velli, Marco, Verdini, A., Verscharen, Daniel, Whittlesey, Phyllis, Wicks, Robert, Bruno, R., and Zimbardo, G.

Subjects

Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics

Abstract

This paper briefly reviews a number of fundamental measurements that need to be made in order to characterize turbulence in space plasmas such as the solar wind. It has long been known that many of these quantities require simultaneous multipoint measurements to attain a proper characterization that would reveal the fundamental physics of plasma turbulence. The solar wind is an ideal plasma for such an investigation, and it now appears to be technologically feasible to carry out such an investigation, following the pioneering Cluster and MMS missions. Quantities that need to be measured using multipoint measurements include the two-point, two-time second correlation function of velocity, magnetic field and density, and higher order statistical objects such as third and fourth order structure functions. Some details of these requirements are given here, with a eye towards achieving closure on fundamental questions regarding the cascade rate, spectral anisotropy, characteristic coherent structures, intermittency, and dissipation mechanisms that describe plasma turbuelence, as well as its variability with plasma parameters in the solar wind. The motivation for this discussion is the current planning for a proposed Helioswarm mission that would be designed to make these measurements,leading to breakthrough understanding of the physics of space and astrophysical turbulence., Comment: White paper submitted to the PLASMA 2020 Decadal Survey Committee

Published

2019

44. Probing Turbulent Scattering Effects on Suprathermal Electrons in the Solar Wind: Modeling, Observations, and Implications

Author

Zaslavsky, Arnaud, primary, Kasper, Justin C., additional, Kontar, Eduard P., additional, Larson, Davin E., additional, Maksimovic, Milan, additional, Marques, José M. D. C., additional, Nicolaou, Georgios, additional, Owen, Christopher J., additional, Romeo, Orlando, additional, and Whittlesey, Phyllis L., additional

Published

2024

45. On the Mesoscale Structure of Coronal Mass Ejections at Mercury’s Orbit: BepiColombo and Parker Solar Probe Observations

Author

Palmerio, Erika, primary, Carcaboso, Fernando, additional, Khoo, Leng Ying, additional, Salman, Tarik M., additional, Sánchez-Cano, Beatriz, additional, Lynch, Benjamin J., additional, Rivera, Yeimy J., additional, Pal, Sanchita, additional, Nieves-Chinchilla, Teresa, additional, Weiss, Andreas J., additional, Lario, David, additional, Mieth, Johannes Z. D., additional, Heyner, Daniel, additional, Stevens, Michael L., additional, Romeo, Orlando M., additional, Zhukov, Andrei N., additional, Rodriguez, Luciano, additional, Lee, Christina O., additional, Cohen, Christina M. S., additional, Rodríguez-García, Laura, additional, Whittlesey, Phyllis L., additional, Dresing, Nina, additional, Oleynik, Philipp, additional, Jebaraj, Immanuel C., additional, Fischer, David, additional, Schmid, Daniel, additional, Richter, Ingo, additional, Auster, Hans-Ulrich, additional, Fraschetti, Federico, additional, and Mierla, Marilena, additional

Published

2024

46. Proton- and Alpha-driven Instabilities in an Ion Cyclotron Wave Event

Author

McManus, Michael D., primary, Klein, Kristopher G., additional, Bale, Stuart D., additional, Bowen, Trevor A., additional, Huang, Jia, additional, Larson, Davin, additional, Livi, Roberto, additional, Rahmati, Ali, additional, Romeo, Orlando, additional, Verniero, Jaye, additional, and Whittlesey, Phyllis, additional

Published

2024

47. HelioSwarm: A Multipoint, Multiscale Mission to Characterize Turbulence

Author

Klein, Kristopher G., primary, Spence, Harlan, additional, Alexandrova, Olga, additional, Argall, Matthew, additional, Arzamasskiy, Lev, additional, Bookbinder, Jay, additional, Broeren, Theodore, additional, Caprioli, Damiano, additional, Case, Anthony, additional, Chandran, Benjamin, additional, Chen, Li-Jen, additional, Dors, Ivan, additional, Eastwood, Jonathan, additional, Forsyth, Colin, additional, Galvin, Antoinette, additional, Genot, Vincent, additional, Halekas, Jasper, additional, Hesse, Michael, additional, Hine, Butler, additional, Horbury, Tim, additional, Jian, Lan, additional, Kasper, Justin, additional, Kretzschmar, Matthieu, additional, Kunz, Matthew, additional, Lavraud, Benoit, additional, Le Contel, Olivier, additional, Mallet, Alfred, additional, Maruca, Bennett, additional, Matthaeus, William, additional, Niehof, Jonathan, additional, O’Brien, Helen, additional, Owen, Christopher, additional, Retinò, Alessandro, additional, Reynolds, Christopher, additional, Roberts, Owen, additional, Schekochihin, Alexander, additional, Skoug, Ruth, additional, Smith, Charles, additional, Smith, Sonya, additional, Steinberg, John, additional, Stevens, Michael, additional, Szabo, Adam, additional, TenBarge, Jason, additional, Torbert, Roy, additional, Vasquez, Bernard, additional, Verscharen, Daniel, additional, Whittlesey, Phyllis, additional, Wickizer, Brittany, additional, Zank, Gary, additional, and Zweibel, Ellen, additional

Published

2023

48. Are Switchback Boundaries Observed by Parker Solar Probe Closed?

Author

Bizien, Nina, primary, Dudok de Wit, Thierry, additional, Froment, Clara, additional, Velli, Marco, additional, Case, Anthony W., additional, Bale, Stuart D., additional, Kasper, Justin, additional, Whittlesey, Phyllis, additional, MacDowall, Robert, additional, and Larson, Davin, additional

Published

2023

49. The multi-point assessment of the kinematics of shocks (MAKOS)

Author

Goodrich, Katherine, primary, Cohen, Ian J., additional, Schwartz, Steven, additional, Wilson, Lynn B., additional, Turner, Drew, additional, Caspi, Amir, additional, Smith, Keith, additional, Rose, Randall, additional, Whittlesey, Phyllis, additional, and Plaschke, Ferdinand, additional

Published

2023

50. The Temperature, Electron, and Pressure Characteristics of Switchbacks: Parker Solar Probe Observations

Author

Huang, Jia, primary, Kasper, Justin C., additional, Larson, Davin E., additional, McManus, Michael D., additional, Whittlesey, Phyllis, additional, Livi, Roberto, additional, Rahmati, Ali, additional, Romeo, Orlando, additional, Liu, Mingzhe, additional, Jian, Lan K., additional, Verniero, Jaye L., additional, Velli, Marco, additional, Badman, Samuel T., additional, Rivera, Yeimy J., additional, Niembro, Tatiana, additional, Paulson, Kristoff, additional, Stevens, Michael, additional, Case, Anthony W., additional, Bowen, Trevor A., additional, Pulupa, Marc, additional, Bale, Stuart D., additional, and Halekas, Jasper S., additional

Published

2023