Teresa Nieves‐Chinchilla

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    A[Teresa Nieves‐Chinchilla]
    AC["Associated Concepts (25)"]
    AW["Authored Works (75)"]
    CA["Linked Co-Authors (88)"]
    CI["Linked Collaborating Institutions (91)"]
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ORCiD

https://orcid.org/0000-0003-0565-4890

OpenAlex ID

https://openalex.org/A5054993564 (API record)

Associated Concepts [?]

• Physics
• Quantum mechanics
• Magnetic field
• Nuclear physics
• Plasma
• Solar wind
• Astronomy
• Coronal mass ejection
• Engineering
• Geology
• Computer science
• Geography
• Astrophysics
• Meteorology
• Mathematics
• Biology
• Interplanetary spaceflight
• Chemistry
• Organic chemistry
• Materials science
• Metallurgy
• Heliosphere
• Flux (metallurgy)
• Interplanetary magnetic field
• Aerospace engineering

Authored Works

sorted by decreasing year, and then by display-name

• Writhed Magnetic Flux Rope Model
• Uninterrupted Tracking of Solar Wind Outflows Along Radial and Non-Radial Paths
• Understanding the Internal Structure of the Heliospheric Flux-Ropes
• The Unusual Widespread Solar Energetic Particle Event on 2013 August 19: Solar Origin and Particle Longitudinal Distribution
• Solar Orbiter: First science results from the nominal mission phase
• Progressing Towards Faraday Rotation Tomography of Coronal Mass Ejections
• Observations of an Interplanetary Coronal Mass Ejection with 100° Angular Separation
• Multispacecraft Heliospheric Mission: Science Case and Concepts
• Multipoint Probing of a Large-scale Complex Heliospheric Structure Knocking a Series of Satellites in February 2022
• Machine Learning Approach to Identifying Flux Rope Orientation
• Investigation of Interplanetary Coronal Mass Ejection Evolutionary Features: Insights from Inner Heliospheric Observatories
• Investigating the Effects of Erosion in Magnetic Flux Ropes
• Investigating Magnetic Structure in the Inner Heliosphere using Faraday Rotation, the FETCH instrument on the MOST mission
• In situ composition measurements of ICME prominence material with Solar Orbiter
• Hydrodynamic Modeling of Quiet-Sun Coronal Loops
• Determination of CME Structures with Faraday Rotation of Spacecraft Radio Signals: the FETCH Instrument on the MOST Mission.
• Beyond Basic Drag - Effects of Solar Wind Pile-Up and High Speed Streams on CME Evolution
• Understanding the Internal Magnetic Field Structure of Interplanetary Coronal Mass Ejections Observed by Helios 1, Helios 2, and MESSENGER
• Towards a Coherent View of the Sun/Corona/Heliosphere: Combining Remote Sensing Data Products with PSP In Situ Measurements
• The kink stability drivers in heliospheric magnetic flux ropes
• Studying the evolution and propagation of a prominent solar wind structure observed by PSP on June 13, 2020
• SoloHI Observations of a Deformed, Concave CME
• Solar Orbiter: Starting the Nominal Mission Phase
• Solar Orbiter Energetic Particle Detector: Early Results and Science Data Center
• Novel Magnetic Field and Electron Density Measurements of CMEs (within AU) with the Proposed Multiview Observatory for Solar Terrestrial Science (MOST) Mission
• Modelling deformable and curved ICME flux rope structures
• Modeling Interplanetary Expansion and Deformation of Coronal Mass Ejections With ANTEATR-PARADE
• Identification of Flux Rope Orientation using Neural Networks
• FETCH Concept: Investigating Quiescent and Transient Magnetic Structures in the Inner Heliosphere using Faraday Rotation of Spacecraft Radio Signals
• Evidence of a complex structure within the 2013 August 19 CME. ICME radial and longitudinal evolution in the heliosphere.
• Effect of the evolution in the Heliospheric Flux-Ropes
• Direct First PSP Observation Of The Interaction Of Two Successive Interplanetary Coronal Mass Ejections On November 2020
• Unraveling the Internal Magnetic Field Structure of the Earth-directed Interplanetary Coronal Mass Ejections During 1995 - 2015
• The Solar Orbiter Mission - Getting Ready for Launch
• Redefining the Magnetic Field Structure of CMEs
• Parker Solar Probe Observations of the Release of Density Blobs and Flux Ropes at the Heliospheric Current Sheet
• Parker Solar Probe Observations of Solar Energetic Particles Associated with a Slow Coronal Mass Ejection at 0.25AU
• Identifying Flux Ropes signatures using Deep Learning
• Following the evolution of coronal mass ejections across the heliosphere
• FIDO-SIT: The First Forward Model for the In Situ Magnetic Field of CME-Driven Sheaths
• Early Evolution and Propagation of a Coronal mass Ejections within 55 solar radii as seen by Parker Solar Probe
• Analysis of the Internal Structure of the Streamer Blow Out Observed the Parker Solar Probe during the First Solar Encounter
• The Internal Structure of ICMEs: Heavy Ion Composition and the Associated Magnetic Field
• Statistical method to characterize the mean shape form of interplanetary shocks and its relation with ICMEs at 1 AU.
• Revisiting Wind's Prograde Orbits During SC23 Maximum: Coronal Mass Ejections
• Reconstruction of the near-Earth interplanetary coronal mass ejections during 1995-2015: Catalog of geometrical and physical properties
• More on the internal structure of Coronal Magnetic Eruptions
• MMS FPI Observations of Flux Transfer Events with Cold Ions at the Dayside Magnetopause
• How can machine learning help us to analyze CME's data?
• Evolution of a coronal mass ejection from the Sun to Saturn
• Analysis of Interplanetary Coronal Mass Ejections (ICMEs) Observed by Wind, DSCOVR and STEREO
• Investigations of Wind/WAVES Dust Impacts
• A model for heliospheric flux-ropes
• The ForeCAT In Situ Data Observer and the Effects of Deflection and Rotation on CME Geoeffectiveness
• Fitting and Reconstruction of Simple Flux Rope CMEs
• Elliptic-cylindrical analytical flux-rope model for ICMEs
• Modeling Magnetic Flux-Ropes Structures
• The Great "Non-Event" of 7 January 2014: Challenges in CME Arrival Time and Geomagnetic Storm Strength Prediction
• On Modeling Flux Rope-type Small Interplanetary Transients by Non-Force Free Methods
• Forecasting the magnetic vectors within a CME at L1 by using solar observations.
• Earth-Directed ICME Magnetic Field Configurations
• Inner Heliospheric Evolution of a 'Stealth' CME Derived From Multi-view Imaging and Multipoint In-situ observations
• Magnetic Field Structure in ICMEs: Comparison and Validity of Different Models
• Combining remote and in-situ observations to learn about CME evolution
• A General Purpose Experiment Controller for low cost Space Application
• The role of CMEs in the lateral spread of electron events in the inner heliosphere
• CMEs in the the Interplanetary Medium : analysis from the Sun to 1 AU
• Solar Wind Halo Formation by the Scattering of the Strahl: Direct Cluster/PEACE Observations of the 3D Velocity Distribution Function
• Connecting CME expansion from Sun to 1 AU
• PROPAGATION AND EVOLUTION OF THE JUNE 1st 2008 CME IN THE INTERPLANETARY MEDIUM
• Variations of Strahl Properties With Fast and Slow Solar Wind
• Multi-spacecraft Recovery of a Magnetic Cloud and its Origin From Magnetic Reconnection on the Sun
• Cluster/PEACE Electrons Velocity Distribution Function: Modeling the Strahl in the Solar Wind
• Following the geomagnetic activity: events on September and October (1999)
• Elliptical Cross Section Model for the Topology of Magnetic Clouds

Linked Co-Authors

• A. Aran
• A. B. Galvin
• A. Koval
• A. P. Walsh
• A. Vourlidas
• A. W. Case
• Ali Rahmati
• Andreas J. Weiss
• Astrid Veronig
• Ayris Narock
• B. J. Lynch
• B. J. Thompson
• B. L. Alterman
• Bernd Heber
• Bin Zhuang
• Brian E. Wood
• C. Kay
• C. M. S. Cohen
• Charles J. Farrugia
• Charles W. Smith
• Christian Möstl
• Christina O. Lee
• D. G. Lloveras
• D. Lario
• D. Malaspina
• D. Müller
• Daniel B. Seaton
• Daniel Pacheco
• David B. Wexler
• David R. Williams
• E. A. Jensen
• Erika Palmerio
• Fernando Carcaboso
• G. C. Ho
• G. M. Mason
• I. Zouganelis
• J. C. Kasper
• J. G. Luhmann
• J. L. Freiherr von Forstner
• J. M. Raines
• J. Rodrı́guez-Pacheco
• J. W. Bonnell
• Jason Kooi
• Jia Huang
• K. E. Korreck
• K. Goetz
• K. W. Paulson
• L. F. Guedes dos Santos
• L. K. Jian
• L. M. Kistler
• M. L. Mays
• M. Pulupa
• Manuela Temmer
• Martin A. Reiss
• Mateja Dumbović
• Miho Janvier
• N. E. Raouafi
• N. Gopalswamy
• N. M. Viall
• N. Nitta
• Nathalia Alzate
• Noé Lugaz
• O. Malandraki
• P. Louarn
• P. Lowrance
• Phillip Hess
• Qian Gong
• R. C. Allen
• R. C. Colaninno
• R. M. Dewey
• R. M. Winslow
• Rachael Filwett
• Robert F. Wimmer‐Schweingruber
• Robert J. Lillis
• Roger C. Bailey
• Rui Pinto
• S. D. Bale
• S. F. Fung
• S. Livi
• S. T. Lepri
• Sanchita Pal
• Simone Di Matteo
• Stefaan Poedts
• T. Dudok de Wit
• T. W. Narock
• Tanja Amerstorfer
• Tatiana Niembro
• Zigong Xu

Linked Collaborating Institutions

• ADNET Systems Inc., Greenbelt, Maryland
• Aberystwyth University, UK
• Austrian Academy of Sciences
• Austrian Institute of Space Science Research
• Boston University, Department of Astronomy
• Boston University, Massachusetts
• California Institute of Technology
• Catholic University, Department of Physics
• Catholic University, Institute for Astrophysics and Computational Sciences
• Catholic University, Washington DC
• Central Institute for Meteorology and Geodynamics, Austria
• Christian Albrechts University of Kiel, Germany
• E.O. Hulburt Center for Space Research, NRL
• Ecole Polytechnique, LPP, Laboratoire de Physique des Plasmas
• European Science and Astronomy Center
• European Space Research and Technology Centre
• George Mason University, Virginia
• Goddard Space Flight Center, Astrophysics Division
• Goucher College, Maryland
• Imperial College, Department of Physics
• Imperial College, London
• Infrared Processing and Analysis Center
• Institut d'Astrophysique Spatiale
• Institute for Astronomy, Astrophysics, Space Applications and Remote Sensing
• JAXA Japan Aerospace Exploration Agency
• Jet Propulsion Laboratory
• Johns Hopkins University, Applied Physics Laboratory
• Johns Hopkins University, Maryland
• KF University of Graz, Institute of Geophysics, Astrophysics and Meteorology
• KF University of Graz, Institute of Physics
• Karl Franzens University of Graz, Austria
• Katholieke University of Leuven, Astronomical Institute
• Katholieke University of Leuven, Belgium
• Korea Astronomy and Space Science Institute
• Laboratoire de Physique et de Chimie de l'Environnement et de l'Espace, Orleans
• Leibniz Institute for Astrophysics, Potsdam
• Lockheed Martin, Palo Alto
• MSU, Institute of Nuclear Physics
• Max-Planck-Institute for Solar System Research, Lindau
• NASA Goddard Space Flight Center, Maryland
• National Autonomous University of Mexico
• National Observatory of Athens, Greece
• National Oceanic and Atmospheric Administration, Boulder
• National Radio Astronomy Observatory, Virginia
• National Solar Observatory, Sunspot New Mexico
• NorthWest Research Associates, Boulder
• Observatoire de Paris, France
• Planetary Science Institute, Arizona
• Princeton University, Department of Astrophysical Sciences
• Rensselaer Polytechnic Institute, New York
• Royal Observatory of Belgium, Department of Solar Physics
• Rutherford Appleton Laboratory
• Skolkovo Institute of Science and Technology, Russia
• Smithsonian Astrophysical Observatory
• Southwest Research Institute, Boulder
• Southwest Research Institute, Texas
• Swedish Institute of Space Physics, Kiruna
• Technical University of Graz, Austria
• U.S. Department of the Navy, Naval Research Laboratory, Washington DC
• UMass Lowell
• University College London, Mullard Space Science Laboratory
• University College London, UK
• University of Alcala, Spain
• University of Arizona
• University of Arizona, Department of Planetary Sciences
• University of Barcelona, Spain
• University of California, Berkeley
• University of California, Berkeley, Space Sciences Laboratory
• University of Colorado, Boulder
• University of Colorado, Boulder, Laboratory for Atmospheric and Space Physics
• University of Delaware
• University of Hawaii, Manoa, Institute for Astronomy
• University of Helsinki, Department of Physics
• University of Helsinki, Finland
• University of Innsbruck, Institute of Astrophysics
• University of Iowa
• University of Iowa, Department of Physics and Astronomy
• University of Kiel, Institute for Experimental and Applied Physics
• University of Leicester, UK
• University of Malaga, Spain
• University of Maryland, Baltimore County
• University of Maryland, College Park
• University of Michigan
• University of Minnesota, Twin Cities
• University of New Hampshire
• University of New Hampshire, Department of Physics and Astronomy
• University of New Hampshire, Institute for the Study of Earth Oceans and Space
• University of North Dakota
• University of Sao Paulo, Brazil
• University of Turku, Finland
• University of Zagreb, Croatia

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