J. S. Halekas

ORCiD

https://orcid.org/0000-0001-5258-6128

OpenAlex ID

https://openalex.org/A5013242592 (API record)

Associated Concepts [?]

• Physics
• Quantum mechanics
• Nuclear physics
• Magnetic field
• Plasma
• Geology
• Astronomy
• Biology
• Astrobiology
• Solar wind
• Geophysics
• Mars Exploration Program
• Thermodynamics
• Engineering
• Computational physics
• Martian
• Chemistry
• Geography
• Organic chemistry
• Aerospace engineering
• Astrophysics
• Atmospheric sciences
• Ion
• Meteorology
• Magnetosphere

Authored Works

sorted by decreasing year, and then by display-name

• What Does Ion Escape at Mars Depend On? Examining the Correlation Between Different Upstream Solar Wind Drivers and Ion Loss at Mars
• The Radial Evolution of Solar Wind Plasma in the Inner Heliosphere: PSP, Helios and Wind Observations
• The Lunar Vertex Magnetic Field Investigation: Revealing the surface magnetic structure of the lunar magnetic anomaly at Reiner Gamma
• The Baseline Solar Wind
• Switchbacks in the Young Solar Wind: Electron Evolution Observed inside Switchbacks between 0.125 AU and 0.25 AU.
• Statistical Analysis of the Radial Evolution of the Solar Winds between 0.1 and 1 au, and their Semi-empirical Iso-poly Fluid Modeling
• Sources of Ions in the Near-Mars Environment
• Solar Wind- Mars Interaction Under Different Interplanetary Magnetic Field (IMF) Orientations
• Sinuous Aurora at Mars: exploring a new phenomenon with data and models
• SelenITA: A dual-spacecraft lunar CubeSat mission to characterize the near-surface electromagnetic plasma environment
• Seasonal invariance of the Martian Bow Shock structure
• Radial Evolution and Acceleration of the Solar Wind
• Quiescent magnetic field regions in the near-sun solar wind: bulk properties and solar surface connections.
• MAKOS: Multi-point Assessment of the Kinematics of Shocks
• Inhomogeneous Distribution of High-Amplitude Kinetic Alfvén Waves in the Near-Sun Solar Wind
• Identifying Fundamental Upstream Drivers of Ion Escape at Mars Using Machine Learning Methods
• Global ambipolar potentials and electric fields at Mars inferred from MAVEN observations
• Electron Heating Near the Lunar Surface and Implications for Wave-Particle Interactions
• Developing an emission model of photoelectrons and Auger electrons from the sunlit lunar surface and its application to evaluation of the lunar electrostatic environment
• Characterizing Energy Spectra of Precipitating Solar Wind H+ and H- in the Martian Atmosphere
• Characterization of Solar Wind Strahl Electron Scattering Observed by PSP
• Changes in the Martian Magnetosphere due to the Radial Orientation of the Interplanetary Magnetic Field (IMF)
• An Overview of HelioSwarm: A NASA MIDEX Mission to Reveal the Nature of Turbulence in Space Plasmas
• A statistical study of the Moon's plasma environment within Earth's magnetotail
• A Systematic Comparison of the Magnetic Field Distributions of Mars and Venus Under Similar Upstream Conditions
• A Study of Temporal Variability in Mars Discrete Aurora as Observed by EMM EMUS.
• A Statistical Study of the Martian Ionopause and Comparisons with Venus
• A MAVEN case study of radial IMF at Mars: Impacts on the dayside ionosphere
• A Comprehensive Model For Pickup Ion Formation At The Moon
• Using Solar Wind Helium to Probe the Martian Hydrogen Corona
• Using Machine Learning to Characterize Solar Wind Driving of Convection in the Terrestrial Magnetotail Lobes
• To Touch the Sun: Parker Solar Probe and the Alfven Critical Point
• The drivers of the Martian bow shock location: a statistical analysis of Mars Volatile EvolutioN and Mars Express observations
• Switchbacks in the Young Solar Wind: Electron Evolution Observed inside Switchbacks between 0.125 AU and 0.25 AU.
• Switchback systematic orientation near Sun and implications for solar interchange reconnection preferential locations
• Sunward Strahl in Magnetic Field Reversals: Solar Connectivity and Magnetic Topology during Rapid Switchbacks in Parker Solar Probe Fast Electron Data
• Signatures of Atmospheric Sputtering at Mars: Probing Effects of the Solar Wind on the Oxygen Corona Using a Synthesis of MAVEN Measurements at Solar Minimum
• Short Duration Electrostatic Waves with Frequency Shifts in the Solar Wind Sunward of 1/3 AU
• Radial Evolution of the Electron Temperature Derived from the Quasi-Thermal Noise Spectroscopy in the Pristine Solar Wind: Parker Solar Probe Observations
• Quantifying the ambipolar electric field contribution to the solar wind acceleration
• Prevalence of Magnetic Reconnection in the near-Sun Heliospheric Current Sheet
• Plasma Environments and Ion Escape at Mars and Venus under Similar Solar Wind and IMF Conditions
• Patches of the magnetic switchbacks: hints of their origins
• Particles and Fields engineering data analysis and trending for the entire MAVEN mission(2013-2021)
• Parker Solar Probe Observations of the Presence and Absence of Magnetic Reconnection in the Near-Sun Solar Wind Current Sheets
• Parker Solar Probe Observations of Quasi-periodic Whistler Packets near .1 au: Evidence for Cross-scale Coupling?
• Origins of low turbulence, quiescent magnetic field regions in the near-sun solar wind and their peculiar magnetic and anisotropic ion behavior.
• On the Solar Wind Proton Temperature Anisotropy at Mars' Orbital Location
• MAVEN observations of low frequency steepened magnetosonic waves and associated heating of the Martian nightside ionosphere
• MAVEN observations of factors influencing the twisted magnetotail configuration at Mars
• Lunar Plasma Environment in Magnetotail Lobe Conditions. First Results from 3-D Hybrid Kinetic Modeling and Comparison with ARTEMIS Observation
• Langumir/Slow extraordinary mode magnetic signatures with Parker Solar Probe
• Ionospheric Energization and Escape over Martian Crustal Magnetic Fields and Non-Magnetized Regions Compared Using MAVEN Measurements
• Investigating the Moon's Interaction with the Terrestrial Magnetotail Lobe Plasma
• Forces, Electric Fields and Currents at the Martian MPB: MAVEN Observations and Multifluid MHD Simulation Results.
• Exploring a Lunar Magnetic Anomaly: The Lunar Vertex PRISM Mission
• Examining Electrostatic Waves at Harmonics of the Electron Cyclotron Frequency at the Moon
• Empirically determined auroral electron events at Mars - MAVEN observations
• EMM EMUS Observations of Martian Nightside Discrete EUV and FUV Aurora: patterns, variability, drivers, and new spectral features
• Discrete Aurora at Mars: Dependence on Upstream Solar Wind Conditions
• Atmospheric Hydrogen Deposition on Mars From Penetrating Solar Wind Protons
• Analyzing the Sunward Electron Deficit to Understand the Suns Electric Potential
• Analysis on the dependence of the Martian Bow Shock on Seasonal and Solar Wind Variations.
• ARTEMIS observations of lunar nightside surface potentials in the magnetotail lobes: Evidence for micrometeoroid impact charging
• A solar source of Alfvenic magnetic field switchbacks: in situ remnants of magnetic funnels on supergranulation scales
• A Systematic Comparison of the Magnetic Field Distributions of Mars and Venus Under Similar Solar Wind Conditions

Linked Co-Authors

• A. B. Galvin
• A. Koval
• A. P. Rouillard
• A. R. Poppe
• A. W. Case
• Abigail Azari
• Alessandro Retinò
• Alexandros Chasapis
• Ali Rahmati
• Amir Caspi
• B. J. Anderson
• B. Lavraud
• B. M. Jakosky
• Beatriz Sánchez‐Cano
• Bennett A. Maruca
• Bernard J. Vasquez
• Brett W. Denevi
• C. A. Cattell
• C. A. Colpitts
• C. C. Chaston
• C. Forsyth
• C. Froment
• C. J. Owen
• C. M. Fowler
• C. S. Reynolds
• C. S. Salem
• C. T. Russell
• Charles W. Smith
• Chen Shi
• Christina O. Lee
• Christy Lentz
• Chuanfei Dong
• D. Malaspina
• D. T. Blewett
• Daniel Verscharen
• David M. Miles
• David Mitchell
• E. Hanson
• Emily Lichko
• F. Eparvier
• Ferdinand Plaschke
• G. A. DiBraccio
• G. B. Hospodarsky
• G. Boscoboinik
• G. C. Ho
• G. M. Holsclaw
• G. P. Zank
• Gangkai Poh
• H. Fuqua Haviland
• Harlan E. Spence
• Heather Meyer
• Hideyuki Usui
• I. Zouganelis
• J. C. Kasper
• J. E. P. Connerney
• J. F. Cooper
• J. F. Drake
• J. G. Luhmann
• J. G. Mitchell
• J. Gruesbeck
• J. L. Verniero
• J. P. Eastwood
• J. T. Niehof
• J. T. Steinberg
• J. W. Bonnell
• Jared Espley
• Jean‐Claude Gérard
• Jia Huang
• Jonas Sousasantos
• Joshua Cahill
• Justin Deighan
• K. E. Korreck
• K. G. Klein
• K. Goetz
• K. W. Paulson
• Karine Issautier
• Karl‐Heinz Glaßmeier
• Krishnaprasad Chirakkil
• L. Andersson
• L. Claire Gasque
• L. D. Woodham
• L. K. Jian
• L. L. Hood
• Laura Berčič
• Leonardo Regoli
• Li‐Jen Chen
• Lucas Liuzzo
• M. A. Shay
• M. Hesse
• M. I. Desai
• M. Kretzschmar
• M. Moncuquet
• M. O. Fillingim
• M. Pulupa
• M. R. Argall
• M. Øieroset
• Michael Chaffin
• Mingzhe Liu
• N. E. Raouafi
• N. Fargette
• N. R. Schnepf
• Nicholas M. Schneider
• Norberto Romanelli
• Oleksiy Agapitov
• Olga Alexandrova
• Omar Leon
• Orlando Romeo
• P. J.
• P. Kollmann
• P. Louarn
• Philippe Garnier
• Prayash Sharma Pyakurel
• R. A. Qudsi
• R. B. Torbert
• R. J. MacDowall
• R. L. Klima
• R. M. Skoug
• R. P. Sawyer
• Robert J. Lillis
• Robin Ramstad
• S. Curry
• S. D. Bale
• S. England
• S. J. Schwartz
• S. K. Vines
• S. M. Tikoo
• S. Ruhunusiri
• S. T. Badman
• Sarah Henderson
• Shaosui Xu
• Sonal Jain
• Susarla Raghuram
• Sven Simon
• T. D. Phan
• T. Dudok de Wit
• T. Woolley
• Tatiana Niembro
• Tristan Weber
• V. Krasnoselskikh
• Victor Réville
• W. H. Matthaeus
• X. Cao
• Xiaohua Fang
• Y. Dong
• Y. Ma
• Yohei Miyake
• Yoshifumi Futaana
• Yuki Harada
• Yuri V. Khotyaintsev
• Z. Girazian
• Zachariah Milby

Linked Collaborating Institutions

• Austrian Academy of Sciences
• Austrian Institute of Space Science Research
• Brazilian National Institute for Space Research
• Centre National de la Recherche Scientifique, France
• Ecole Polytechnique, LPP, Laboratoire de Physique des Plasmas
• European Science and Astronomy Center
• Georgia Institute of Technology
• Howard University, Washington DC
• Imperial College, London
• Instituto Tecnologico de Aeronautica, Centro Tecnico Aeroespacial
• Johns Hopkins University, Applied Physics Laboratory
• Johns Hopkins University, Maryland
• Khalifa University of Science Technology and Research, UAE
• Kobe University, Japan
• Kyoto University, Japan
• Laboratoire de Physique et de Chimie de l'Environnement et de l'Espace, Orleans
• Los Alamos National Laboratory, New Mexico
• NASA Ames Research Center
• NASA Goddard Space Flight Center, Maryland
• NASA Marshall Space Flight Center
• Observatoire de la Cote d'Azur, France
• Planetary Science Institute, Arizona
• Princeton University, New Jersey
• Queen Mary University, UK
• Smithsonian Astrophysical Observatory
• Southwest Research Institute, Boulder
• Southwest Research Institute, Texas
• Stanford University, California
• Swedish Institute of Space Physics, Kiruna
• Technical University of Braunschweig, Germany
• U.S. Environmental Protection Agency
• Umea University, Sweden
• Universite de Toulouse Paul Sabatier, France
• University College London, Mullard Space Science Laboratory
• University of Alberta, Canada
• University of Arizona
• University of Buenos Aires, Argentina
• University of California, Berkeley
• University of California, Berkeley, Space Sciences Laboratory
• University of California, Los Angeles
• University of California, Los Angeles, Institute of Geophysics and Planetary Physics
• University of Cambridge, UK
• University of Colorado, Boulder
• University of Colorado, Boulder, Laboratory for Atmospheric and Space Physics
• University of Delaware
• University of Florence, Italy
• University of Iowa
• University of Iowa, Department of Physics and Astronomy
• University of Leicester, UK
• University of Liege, Belgium
• University of Maryland, Baltimore County
• University of Maryland, College Park
• University of Michigan
• University of Minnesota, Twin Cities
• University of New Hampshire
• University of Oslo, Norway
• University of Otago, New Zealand
• University of Oxford, UK
• University of Sherbrooke, Canada
• University of Texas, Austin
• University of Texas, San Antonio
• University of Tokyo, Japan
• University of Wisconsin, Madison
• Virginia Polytechnic Institute and State University
• West Virginia University

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