Your search keyword '"Veerle J. Sterken"' showing total 15 results

1. Enabling technologies for planetary exploration

Author

Manuel Grande, Linli Guo, Michel Blanc, Jorge Alves, Advenit Makaya, Sami Asmar, David Atkinson, Anne Bourdon, Pascal Chabert, Steve Chien, John Day, Alberto G. Fairén, Anthony Freeman, Antonio Genova, Alain Herique, Wlodek Kofman, Joseph Lazio, Olivier Mousis, Gian Gabriele Ori, Victor Parro, Robert Preston, Jose A. Rodriguez-Manfredi, Veerle J. Sterken, Keith Stephenson, Joshua Vander Hook, J. Hunter Waite, and Sonia Zine

Published

2023

2. Contributors

Author

Jorge Alves, Eleonora Ammannito, Nicolas André, Gabriella Arrigo, Sami Asmar, David Atkinson, Adriano Autino, Pierre Beck, Gilles Berger, Michel Blanc, Scott Bolton, Anne Bourdon, Pierre Bousquet, Emma Bunce, Maria Teresa Capria, Pascal Chabert, Sébastien Charnoz, Baptiste Chide, Steve Chien, Ilaria Cinelli, John Day, Véronique Dehant, Brice Demory, Shawn Domagal-Goldman, Caroline Dorn, Alberto G. Fairén, Valerio Filice, Leigh N. Fletcher, Bernard Foing, François Forget, Anthony Freeman, B. Scott Gaudi, Antonio Genova, Manuel Grande, James Green, Léa Griton, Linli Guo, Heidi Hammel, Christiane Heinicke, Ravit Helled, Kevin Heng, Alain Herique, Dennis Höning, Joshua Vander Hook, Aurore Hutzler, Takeshi Imamura, Caitriona Jackman, Yohai Kaspi, Jyeong Ja Kim, Daniel Kitzman, Wlodek Kofman, Eiichiro Kokubo, Oleg Korablev, Jérémie Lasue, Joseph Lazio, Jérémy Leconte, Emmanuel Lellouch, Louis Le Sergeant d'Hendecourt, Jonathan Lewis, Ming Li, Steve Mackwell, Mohammad Madi, Advenit Makaya, Nicolas Mangold, Bernard Marty, Sylvestre Maurice, Ralph McNutt, Patrick Michel, Alessandro Morbidelli, Christoph Mordasini, Olivier Mousis, David Nesvorny, Lena Noack, Masami Onoda, Merav Opher, Gian Gabriele Ori, James Owen, Chris Paranicas, Victor Parro, Maria Antonietta Perino, Christina Plainaki, Robert Preston, Olga Prieto-Ballesteros, Liping Qin, Sascha Quanz, Heike Rauer, Jose A. Rodriguez-Manfredi, Juergen Schmidt, Dave Senske, Ignas Snellen, Krista M. Soderlund, Christophe Sotin, Linda Spilker, Tilman Spohn, Keith Stephenson, Veerle J. Sterken, Leonardo Testi, Nicola Tosi, Yoshio Toukaku, Stéphane Udry, Ann C. Vandaele, Allona Vazan, Julia Venturini, Pierre Vernazza, J. Hunter Waite, Joachim Wambsganss, Armin Wedler, Frances Westall, Philippe Zarka, Sonia Zine, and Qiugang Zong

Published

2023

3. Investigating the outer regions of the heliosphere with measurements and simulations of interstellar dust

Author

Lennart Robin Baalmann, Silvan Hunziker, Peter Strub, David Malaspina, Urs Schroffenegger, Harald Krüger, Mark Hervig, Allison N. Jaynes, William Kurth, Lynn B. Wilson III, and Veerle J. Sterken

Abstract

Interstellar dust has been and will be measured by many spacecraft, both directly (e.g. by Cassini, Ulysses, DESTINY+, IMAP) and indirectly (e.g. by Voyager, Wind). The flux of interstellar dust at these spacecraft can be enhanced, in particular for small dust grains (Through their surface charges, these small particles are coupled to the solar-cycle-dependent magnetic fields inside and to interstellar fields outside of the heliosphere. By comparing the measurements to simulations of interstellar dust, inferences about the outer regions of the heliosphere and its boundary can be made. The quality of these inferences highly depends on the availability of detailed measurements of interstellar dust, highlighting the necessity of a space-based dust detector operating during the upcoming focusing phase, such as the proposed DOLPHIN mission.In this talk we give an overview of measurements and simulations of the measurements of various missions so far, and their link to interstellar dust simulations.

Published

2022

4. Final reports of the Stardust Interstellar Preliminary Examination

Author

Andrew J. Westphal, Hans A. Bechtel, Frank E. Brenker, Anna L. Butterworth, George Flynn, David R. Frank, Zack Gainsforth, Jon K. Hillier, Frank Postberg, Alexandre S. Simionovici, Veerle J. Sterken, Rhonda M. Stroud, Carlton Allen, David Anderson, Asna Ansari, Saša Bajt, Ron K. Bastien, Nabil Bassim, Janet Borg, John Bridges, Donald E. Brownlee, Mark Burchell, Manfred Burghammer, Hitesh Changela, Peter Cloetens, Andrew M. Davis, Ryan Doll, Christine Floss, Eberhard Grün, Philipp R. Heck, Peter Hoppe, Bruce Hudson, Joachim Huth, Brit Hvide, Anton Kearsley, Ashley J. King, Barry Lai, Jan Leitner, Laurence Lemelle, Hugues Leroux, Ariel Leonard, Robert Lettieri, William Marchant, Larry R. Nittler, Ryan Ogliore, Wei Ja Ong, Mark C. Price, Scott A. Sandford, Juan‐Angel Sans Tresseras, Sylvia Schmitz, Tom Schoonjans, Geert Silversmit, Vicente A. Solé, Ralf Srama, Frank Stadermann, Thomas Stephan, Julien Stodolna, Steven Sutton, Mario Trieloff, Peter Tsou, Akira Tsuchiyama, Tolek Tyliszczak, Bart Vekemans, Laszlo Vincze, Joshua Von Korff, Naomi Wordsworth, Daniel Zevin, and Michael E. Zolensky

Published

2014

5. Stardust Interstellar Preliminary Examination IV: Scanning transmission X‐ray microscopy analyses of impact features in the Stardust Interstellar Dust Collector

Author

Anna L. Butterworth, Andrew J. Westphal, Tolek Tyliszczak, Zack Gainsforth, Julien Stodolna, David R. Frank, Carlton Allen, David Anderson, Asna Ansari, Saša Bajt, Ron K. Bastien, Nabil Bassim, Hans A. Bechtel, Janet Borg, Frank E. Brenker, John Bridges, Donald E. Brownlee, Mark Burchell, Manfred Burghammer, Hitesh Changela, Peter Cloetens, Andrew M. Davis, Ryan Doll, Christine Floss, George Flynn, Eberhard Grün, Philipp R. Heck, Jon K. Hillier, Peter Hoppe, Bruce Hudson, Joachim Huth, Brit Hvide, Anton Kearsley, Ashley J. King, Barry Lai, Jan Leitner, Laurence Lemelle, Hugues Leroux, Ariel Leonard, Robert Lettieri, William Marchant, Larry R. Nittler, Ryan Ogliore, Wei Ja Ong, Frank Postberg, Mark C. Price, Scott A. Sandford, Juan‐Angel Sans͂ Tresseras, Sylvia Schmitz, Tom Schoonjans, Geert Silversmit, Alexandre S. Simionovici, Vicente A. Solé, Ralf Srama, Frank J. Stadermann, Thomas Stephan, Veerle J. Sterken, Rhonda M. Stroud, Steven Sutton, Mario Trieloff, Peter Tsou, Akira Tsuchiyama, Bart Vekemans, Laszlo Vincze, Joshua Von Korff, Naomi Wordsworth, Daniel Zevin, and Michael E. Zolensky

Published

2014

6. Space Plasma Physics: A Review

Author

Bruce T. Tsurutani, Gary P. Zank, Veerle J. Sterken, Kazunari Shibata, Tsugunobu Nagai, Anthony J. Mannucci, David M. Malaspina, Gurbax S. Lakhina, Shrikanth G. Kanekal, Keisuke Hosokawa, Richard B. Horne, Rajkumar Hajra, Karl-Heinz Glassmeier, C. Trevor Gaunt, Peng-Fei Chen, and Syun-Ichi Akasofu

Subjects

Nuclear and High Energy Physics, Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics, FOS: Physical sciences, Condensed Matter Physics, Space Physics (physics.space-ph), Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

Owing to the ever-present solar wind, our vast solar system is full of plasmas. The turbulent solar wind, together with sporadic solar eruptions, introduces various space plasma processes and phenomena in the solar atmosphere all the way to the Earth's ionosphere and atmosphere and outward to interact with the interstellar media to form the heliopause and termination shock. Remarkable progress has been made in space plasma physics in the last 65 years, mainly due to sophisticated in-situ measurements of plasmas, plasma waves, neutral particles, energetic particles, and dust via space-borne satellite instrumentation. Additionally high technology ground-based instrumentation has led to new and greater knowledge of solar and auroral features. As a result, a new branch of space physics, i.e., space weather, has emerged since many of the space physics processes have a direct or indirect influence on humankind. After briefly reviewing the major space physics discoveries before rockets and satellites, we aim to review all our updated understanding on coronal holes, solar flares and coronal mass ejections, which are central to space weather events at Earth, solar wind, storms and substorms, magnetotail and substorms, emphasizing the role of the magnetotail in substorm dynamics, radiation belts/energetic magnetospheric particles, structures and space weather dynamics in the ionosphere, plasma waves, instabilities, and wave-particle interactions, long-period geomagnetic pulsations, auroras, geomagnetically induced currents (GICs), planetary magnetospheres and solar/stellar wind interactions with comets, moons and asteroids, interplanetary discontinuities, shocks and waves, interplanetary dust, space dusty plasmas and solar energetic particles and shocks, including the heliospheric termination shock. This paper is aimed to provide a panoramic view of space physics and space weather., Accepted for publication in IEEE Transactions on Plasma Science (2022)

Published

2022

7. A Multi-purpose Heliophysics L4 Mission

Author

Arik Posner, Charles Nickolos Arge, Jan Staub, Orville C StCyr, David C Folta, Sami K. Solanki, Roelf Du Toit Strauss, Frederic Effenberger, Achim Gandorfer, Bernd Heber, Carl John Henney, Johann Hirzberger, Shaela Jones, Patrick Kuehl, Olga Malandraki, and Veerle J Sterken

Published

2021

8. Interstellar Dust in the Solar System

Author

Veerle J. Sterken, Andrew J. Westphal, Nicolas Altobelli, David Malaspina, and Frank Postberg

Subjects

Space and Planetary Science, Astronomy and Astrophysics

Published

2019

9. Interstellar dust. Evidence for interstellar origin of seven dust particles collected by the Stardust spacecraft

Author

Andrew J, Westphal, Rhonda M, Stroud, Hans A, Bechtel, Frank E, Brenker, Anna L, Butterworth, George J, Flynn, David R, Frank, Zack, Gainsforth, Jon K, Hillier, Frank, Postberg, Alexandre S, Simionovici, Veerle J, Sterken, Larry R, Nittler, Carlton, Allen, David, Anderson, Asna, Ansari, Saša, Bajt, Ron K, Bastien, Nabil, Bassim, John, Bridges, Donald E, Brownlee, Mark, Burchell, Manfred, Burghammer, Hitesh, Changela, Peter, Cloetens, Andrew M, Davis, Ryan, Doll, Christine, Floss, Eberhard, Grün, Philipp R, Heck, Peter, Hoppe, Bruce, Hudson, Joachim, Huth, Anton, Kearsley, Ashley J, King, Barry, Lai, Jan, Leitner, Laurence, Lemelle, Ariel, Leonard, Hugues, Leroux, Robert, Lettieri, William, Marchant, Ryan, Ogliore, Wei Jia, Ong, Mark C, Price, Scott A, Sandford, Juan-Angel, Sans Tresseras, Sylvia, Schmitz, Tom, Schoonjans, Kate, Schreiber, Geert, Silversmit, Vicente A, Solé, Ralf, Srama, Frank, Stadermann, Thomas, Stephan, Julien, Stodolna, Stephen, Sutton, Mario, Trieloff, Peter, Tsou, Tolek, Tyliszczak, Bart, Vekemans, Laszlo, Vincze, Joshua, Von Korff, Naomi, Wordsworth, Daniel, Zevin, and Michael E, Zolensky

Abstract

Seven particles captured by the Stardust Interstellar Dust Collector and returned to Earth for laboratory analysis have features consistent with an origin in the contemporary interstellar dust stream. More than 50 spacecraft debris particles were also identified. The interstellar dust candidates are readily distinguished from debris impacts on the basis of elemental composition and/or impact trajectory. The seven candidate interstellar particles are diverse in elemental composition, crystal structure, and size. The presence of crystalline grains and multiple iron-bearing phases, including sulfide, in some particles indicates that individual interstellar particles diverge from any one representative model of interstellar dust inferred from astronomical observations and theory.

Published

2014

10. Interstellar Dust Flow through the Solar System

Author

Peter Strub, Veerle J. Sterken, Harald Krüger, Eberhard Grün, Mihaly Horanyi, Vladimir Yu. Nosenko, Padma K. Shukla, Markus H. Thoma, and Hubertus M. Thomas

Subjects

Physics, Solar System, Interstellar cloud, Astronomy, Astrophysics::Cosmology and Extragalactic Astrophysics, Dust lane, Interstellar medium, Interplanetary dust cloud, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Circumstellar dust, Astrophysics::Earth and Planetary Astrophysics, Astrophysics::Galaxy Astrophysics, Heliosphere, Cosmic dust

Abstract

The in‐situ dust detector on board the Ulysses spacecraft has collected the most comprehensive dataset of interstellar dust (ISD) particles penetrating the heliosphere between 1992 and 2007.In 2005 we identified a shift in dust flow direction by 50°, whereas before (from 1992 to 2004) it was aligned within 20° with the direction of the undisturbed dust flow through the interstellar environment. Furthermore, in this time period the dust flux shows a steep rise, which is observed in the small particles 4 months ahead of an increase in the larger particle flux. These variations of the dust flux and angular distribution can only be understood in terms of the grain interaction with the heliospheric plasma environment.

Published

2011

11. Dust in and Around the Heliosphere and Astrospheres

Author

'Veerle J. Sterken

12. Dust in and Around the Heliosphere and Astrospheres

Author

Veerle J. Sterken, Lennart R. Baalmann, Bruce T. Draine, Egor Godenko, Konstantin Herbst, Hsiang-Wen Hsu, Silvan Hunziker, Vladislav Izmodenov, Rosine Lallement, and Jonathan D. Slavin

Subjects

Heliosphere, Space and Planetary Science, Astronomy and Astrophysics, LIC, Astrosphere, Cosmic dust, ISM, Interstellar dust

Abstract

Interstellar dust particles were discovered in situ, in the solar system, with the Ulysses mission’s dust detector in 1992. Ever since, more interstellar dust particles have been measured inside the solar system by various missions, providing insight into not only the composition of such far-away visitors, but also in their dynamics and interaction with the heliosphere. The dynamics of interstellar (and interplanetary) dust in the solar/stellar systems depend on the dust properties and also on the space environment, in particular on the heliospheric/astrospheric plasma, and the embedded time-variable magnetic fields, via Lorentz forces. Also, solar radiation pressure filters out dust particles depending on their composition. Charge exchanges between the dust and the ambient plasma occur, and pick-up ions can be created. The role of the dust for the physics of the heliosphere and astrospheres is fairly unexplored, but an important and a rapidly growing topic of investigation. This review paper gives an overview of dust processes in heliospheric and astrospheric environments, with its resulting dynamics and consequences. It discusses theoretical modeling, and reviews in situ measurements and remote sensing of dust in and near our heliosphere and astrospheres, with the latter being a newly emerging field of science. Finally, it summarizes the open questions in the field., Space Science Reviews, 218 (8), ISSN:1572-9672, ISSN:0038-6308

13. SIXTEEN YEARS OF ULYSSES INTERSTELLAR DUST MEASUREMENTS IN THE SOLAR SYSTEM. III. SIMULATIONS AND DATA UNVEIL NEW INSIGHTS INTO LOCAL INTERSTELLAR DUST.

Author

Veerle J. Sterken, Peter Strub, Harald Krüger, Rudolf von Steiger, and Priscilla Frisch

Subjects

*INTERPLANETARY dust, *SOLAR system, *MONTE Carlo method, *PHOTOIONIZATION, *HELIOSPHERE

Abstract

Interstellar dust (ISD) in the solar system was detected in situ for the first time in 1993 by the Ulysses dust detector. The study of ISD is important for understanding its role in star and solar system formation. The goal of this paper is to understand the variability in the ISD observations from the Ulysses mission by using a Monte Carlo simulation of ISD trajectories, with the final aim to constrain the ISD particle properties from simulations and the data. The paper is part of a series of three: Strub et al. describe the variations of the ISD flow from the Ulysses data set, and Krüger et al. focus on its ISD mass distribution. We describe and interpret the simulations of the ISD flow at Ulysses orbit for a wide range of particle properties and discuss four open issues in ISD research: the existence of very big ISD particles, the lack of smaller ISD particles, the shift in dust flow direction in 2005, and particle properties. We conclude that the shift in the dust flow direction in 2005 can best be explained by Lorentz force in the inner heliosphere, but that an extra filtering mechanism is needed to fit the fluxes. A time-dependent filtering in the outer regions of the heliosphere is proposed for this. Also, the high charge-to-mass ratio values found for the heavier particles after 2003 indicate that these particles are lower in density than previously assumed. This method gives new insights into the ISD properties and paves the way toward getting a complete view on the ISD from the local interstellar cloud. We conclude that in combination with the data and simulations, also impact ionization experiments are necessary using low-density dust, in order to constrain the density of the particles. [ABSTRACT FROM AUTHOR]

Published

2015

14. SIXTEEN YEARS OF ULYSSES INTERSTELLAR DUST MEASUREMENTS IN THE SOLAR SYSTEM. II. FLUCTUATIONS IN THE DUST FLOW FROM THE DATA.

Author

Peter Strub, Harald Krüger, and Veerle J. Sterken

Subjects

INTERPLANETARY dust, SOLAR system, PLASMA fluctuations, SOLAR magnetic fields, STELLAR mass

Abstract

The Ulysses spacecraft provided the first opportunity to identify and study interstellar dust (ISD) in situ in the solar system between 1992 and 2007. Here we present the first comprehensive analysis of the ISD component in the entire Ulysses dust data set. We analyzed several parameters of the ISD flow in a time-resolved fashion: flux, flow direction, mass index, and flow width. The general picture is in agreement with a time-dependent focusing/defocusing of the charged dust particles due to long-term variations of the solar magnetic field throughout a solar magnetic cycle of 22 years. In addition, we confirm a shift in dust direction of 50° ± 7° in 2005, along with a steep, size-dependent increase in flux by a factor of 4 within 8 months. To date, this is difficult to interpret and has to be examined in more detail by new dynamical simulations. This work is part of a series of three papers. This paper concentrates on the time-dependent flux and direction of the ISD. In a companion paper we analyze the overall mass distribution of the ISD measured by Ulysses, and a third paper discusses the results of modeling the flow of the ISD as seen by Ulysses. [ABSTRACT FROM AUTHOR]

Published

2015

15. SIXTEEN YEARS OF ULYSSES INTERSTELLAR DUST MEASUREMENTS IN THE SOLAR SYSTEM. I. MASS DISTRIBUTION AND GAS-TO-DUST MASS RATIO.

Author

Harald Krüger, Peter Strub, Eberhard Grün, and Veerle J. Sterken

Subjects

INTERPLANETARY dust, SOLAR system, STELLAR mass, ASTRONOMICAL observations, RADIATION pressure

Abstract

In the early 1990s, contemporary interstellar dust penetrating deep into the heliosphere was identified with the in situ dust detector on board the Ulysses spacecraft. Between 1992 and the end of 2007 Ulysses monitored the interstellar dust stream. The interstellar grains act as tracers of the physical conditions in the local interstellar medium (ISM) surrounding our solar system. Earlier analyses of the Ulysses interstellar dust data measured between 1992 and 1998 implied the existence of a population of “big” interstellar grains (up to 10−13 kg). The derived gas-to-dust-mass ratio was smaller than the one derived from astronomical observations, implying a concentration of interstellar dust in the very local ISM. In this paper we analyze the entire data set from 16 yr of Ulysses interstellar dust measurements in interplanetary space. This paper concentrates on the overall mass distribution of interstellar dust. An accompanying paper investigates time-variable phenomena in the Ulysses interstellar dust data, and in a third paper we present the results from dynamical modeling of the interstellar dust flow applied to Ulysses. We use the latest values for the interstellar hydrogen and helium densities, the interstellar helium flow speed of , and the ratio of radiation pressure to gravity, β, calculated for astronomical silicates. We find a gas-to-dust mass ratio in the local interstellar cloud of and a dust density of (2.1 ± 0.6) × 10−24 kg m−3. For a higher inflow speed of the gas-to-dust mass ratio is 20% higher, and, accordingly, the dust density is lower by the same amount. The gas-to-dust mass ratio derived from our new analysis is compatible with the value most recently determined from astronomical observations. We confirm earlier results that the very local ISM contains “big” (i.e., ≈1 μm sized) interstellar grains. We find a dust density in the local ISM that is a factor of three lower than values implied by earlier analyses. [ABSTRACT FROM AUTHOR]

Published

2015