First dust measurements with the Solar Orbiter Radio and Plasma Wave instrument

Zaslavsky, A.; Mann, Ingrid; Souček, J.; Czechowski, A.; Píša, D.; Vaverka, Jakub; Meyer‐Vernet, N.; Maksimović, Milan; Lorfèvre, E.; Issautier, Karine; Babic, Kristina Rackovic; Bale, S. D.; Vecchio, A.; Chust, T.; Khotyaintsev, Yu. V.; Krasnoselskikh, V.; Kretzschmar, M.; Plettemeier, Dirk; Steller, M.; Štverák, S.; Trávníček, Pavel; Vaivads, A.

doi:10.1051/0004-6361/202140969

Cited by 20 publications

(42 citation statements)

References 51 publications

(53 reference statements)

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“…The dust production was modeled by collisional fragmentation near the Sun and the dust trajectories were calculated with included radiation pressure and Lorentz force terms. Mann and Czechowski (2021) showed that the observed impact rates largely agree with the model calculations for dust > 100 nm and proposed that the differences may be explained by the influence of smaller particles and of other dust components, such as dust in bound orbits and interstellar dust.…”

Section: Exploration Of the Inner Solar Systemsupporting

confidence: 61%

“…Systematic studies of the dust flux near 1 AU are conducted with the Solar Terrestrial Relations Observatory (STEREO) (Zaslavsky et al, 2012) and Wind (Malaspina et al, 2014). The first analyses show that a large fraction of the observed dust particles are repelled from the Sun, i.e., the dust particles are in unbound orbits (Zaslavsky et al, 2021;Szalay et al, 2020;Malaspina et al, 2020). Mann and Czechowski (2021) used model calculations to explain the impact rates observed by the Parker Solar Probe.…”

Section: Exploration Of the Inner Solar Systemmentioning

confidence: 99%

“…The first analyses show that a large fraction of the observed dust particles are repelled from the Sun, i.e., the dust particles are in unbound orbits (Zaslavsky et al, 2021;Szalay et al, 2020;Malaspina et al, 2020). Mann and Czechowski (2021) used model calculations to explain the impact rates observed by the Parker Solar Probe. The dust production was modeled by collisional fragmentation near the Sun and the dust trajectories were calculated with included radiation pressure and Lorentz force terms.…”

Section: Exploration Of the Inner Solar Systemmentioning

confidence: 99%

“…The Solar Orbiter will thus provide long-term, in situ observations of the environment in the inner solar system with multiple instruments. One of these instruments is the Radio and Plasma Waves instrument, allowing observations of the cosmic dust flux with typical diameters ranging from ∼ 100 to ∼ 500 nm (Zaslavsky et al, 2021).…”

Section: Exploration Of the Inner Solar Systemmentioning

confidence: 99%

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Machine learning detection of dust impact signals observed by the Solar Orbiter

et al. 2023

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Abstract. This article presents the results of automatic detection of dust impact signals observed by the Solar Orbiter – Radio and Plasma Waves instrument. A sharp and characteristic electric field signal is observed by the Radio and Plasma Waves instrument when a dust particle impacts the spacecraft at high velocity. In this way, ∼ 5–20 dust impacts are daily detected as the Solar Orbiter travels through the interplanetary medium. The dust distribution in the inner solar system is largely uncharted and statistical studies of the detected dust impacts will enhance our understanding of the role of dust in the solar system. It is however challenging to automatically detect and separate dust signals from the plural of other signal shapes for two main reasons. Firstly, since the spacecraft charging causes variable shapes of the impact signals, and secondly because electromagnetic waves (such as solitary waves) may induce resembling electric field signals. In this article, we propose a novel machine learning-based framework for detection of dust impacts. We consider two different supervised machine learning approaches: the support vector machine classifier and the convolutional neural network classifier. Furthermore, we compare the performance of the machine learning classifiers to the currently used on-board classification algorithm and analyze 2 years of Radio and Plasma Waves instrument data. Overall, we conclude that detection of dust impact signals is a suitable task for supervised machine learning techniques. The convolutional neural network achieves the highest performance with 96 % ± 1 % overall classification accuracy and 94 % ± 2 % dust detection precision, a significant improvement to the currently used on-board classifier with 85 % overall classification accuracy and 75 % dust detection precision. In addition, both the support vector machine and the convolutional neural network classifiers detect more dust particles (on average) than the on-board classification algorithm, with 16 % ± 1 % and 18 % ± 8 % detection enhancement, respectively. The proposed convolutional neural network classifier (or similar tools) should therefore be considered for post-processing of the electric field signals observed by the Solar Orbiter.

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Section: Exploration Of the Inner Solar Systemsupporting

confidence: 61%

Section: Exploration Of the Inner Solar Systemmentioning

confidence: 99%

Section: Exploration Of the Inner Solar Systemmentioning

confidence: 99%

Section: Exploration Of the Inner Solar Systemmentioning

confidence: 99%

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Machine learning detection of dust impact signals observed by the Solar Orbiter

et al. 2023

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“…For particles orbiting at Keplerian speeds, we can assume a typical impact velocity of 30 km.s −1 ; the obtained mass range is then 20 − 340 × 10 −17 kg, which corresponds to the size interval 2 -5 µm (we assume a mass density ρ = 2.5 g.cm −3 ). On the other hand, it has appeared that the fluxes observed on several spacecraft, including STEREO (Zaslavsky et al 2012), but also Parker Solar Probe (Pusack et al 2021) and Solar Orbiter (Zaslavsky et al 2021), are dominated by impacts from a population of dust particles produced close to the Sun and pushed away along hyperbolic orbits by the radiation pressure, the β meteoroids. The velocity of these particles at 1 AU depends quite importantly on their origin and composition, through the value of the β parameter equal to the ratio of the radiation pressure force to the gravitational force on the dust grain.…”

Section: Electron Collectionmentioning

confidence: 99%

An analytical model for dust impact voltage signals, and its application to STEREO/WAVES data

Babic

Zaslavsky²,

Issautier³

et al. 2022

Preprint

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<p>Dust grains are a common constituent of the Solar system. Dust impacts have been observed using radio and wave instruments onboard spacecraft since the 1980s. Voltage waveforms show typical impulsive signals generated by dust grains. We aim at developing models of how signals are generated to be able to link observed electric signals to the physical properties of the impacting dust. To validate the model, we use the Time Domain Sampler (TDS) subsystem of the STEREO/WAVES instrument which generates high-cadence time series of voltage pulses for each monopole. A model that we propose takes into account impact-ionization-charge collection and electrostatic-influence effects. It is an analytical expression for the pulse and allows us to measure the of amount of the total ion charge, the fraction of escaping charge, the rise timescale, and the relaxation timescale. The model is simple and convenient for massive data fitting. To check our model&#8217;s accuracy, we collected all the dust events detected by STEREO/WAVES/TDS simultaneously on all three monopoles at 1AU since the beginning of the STEREO mission in 2007. Our study confirms that the rise time largely exceeds the spacecraft&#8217;s short timescale of electron collection. Our estimated rise time value allows us to determine the propagation speed of the ion cloud, which is the first time that this information has been derived from space data. Our model also makes it possible to determine properties associated with the electron dynamics, in particular the order of magnitude of the electron escape current. The obtained value gives us an estimate of the cloud&#8217;s electron temperature &#8212; a result that, as far as we know, has never been obtained before except in laboratory experiments. Furthermore, a strong correlation between the total cloud charge and the escaping charge allows us to estimate the escaping current from the amplitude of the precursor, a result that could be interesting for the study of the pulses recently observed in the magnetic waveforms of Solar Orbiter or Parker Solar Probe, for which the electric waveform is saturated.</p>

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Energy Design

Sommer¹,

Pont²,

Sommer‐Nawara³

et al. 2023

2023 Bauphysik Kalender

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The term 'α-meteoroid' was introduced to describe a group of micrometeoroids with certain dynamical properties, which-alongside the group of the β-meteoroids-had been identified by the first generation of reliable in-situ dust detectors in interplanetary space. In recent years, use of the term α-meteoroid has become more frequent again, under a subtly but crucially altered definition. This work shall bring attention to the discrepancy between the term's original and newly established meaning, and spotlight the now-overlooked group of particles that the term used to describe. We review past and present pertinent literature around the term α-meteoroid, and assess the dynamics of the originally referred-to particles with respect to possible sources, showing that their formation is the expected consequence of collisional grinding of the zodiacal cloud at short heliocentric distances. The abundance of the original α-meteoroids, which are essentially 'bound β-meteoroids', makes them relevant to all in-situ dust experiments in the inner solar system. Due to the change of the term's meaning, however, they are not considered by contemporary studies. The characterization of this particle population could elucidate the processing of the innermost zodiacal cloud, and should thus be objective of upcoming in-situ dust experiments. The attained ambiguity of the term α-meteoroid is not easily resolved, warranting great care and clarity going forward.

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First dust measurements with the Solar Orbiter Radio and Plasma Wave instrument

Cited by 20 publications

References 51 publications

Machine learning detection of dust impact signals observed by the Solar Orbiter

Machine learning detection of dust impact signals observed by the Solar Orbiter

An analytical model for dust impact voltage signals, and its application to STEREO/WAVES data

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