On the Applicability of Single‐Spacecraft Interferometry Methods Using Electric Field Probes

Steinvall, Konrad; Khotyaintsev, Yuri V.; Graham, Daniel B.

doi:10.1029/2021ja030143

Cited by 7 publications

(6 citation statements)

References 49 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The use of the time delay between V 1 and − V 2 provides the speed estimate of only a few km/s, but these voltage signals were poorly correlated, and the solitary wave was barely propagating along this antenna ( L 12 ≈ − 0.01), which makes the speed estimate highly uncertain (Wang et al., 2021). The revealed solitary wave velocity of about 60 km/s is consistent with the results of electric field interferometry (SM), which is another technique for estimating wave velocities (for example, Graham et al., 2016; Steinvall et al., 2022). Using solitary wave velocity V s = 60 km/s, we compute the electrostatic potential φ = ∫E L V dt and also translate temporal solitary wave profiles into spatial ones.…”

Section: Data and Case Studiessupporting

confidence: 80%

Slow Electron Holes in the Earth's Magnetosheath

Shaikh,

Vasko,

Hutchinson

et al. 2024

JGR Space Physics

View full text Add to dashboard Cite

We present a statistical analysis of electrostatic solitary waves observed aboard Magnetospheric Multiscale spacecraft in the Earth's magnetosheath. Applying single‐spacecraft interferometry to several hundred solitary waves collected in about 2‐minute interval, we show that almost all of them have the electrostatic potential of positive polarity and propagate quasi‐parallel to the local magnetic field with plasma frame velocities of the order of 100 km/s. The solitary waves have typical parallel half‐widths from 10 to 100 m that is between 1 and 10 Debye lengths and typical amplitudes of the electrostatic potential from 10 to 200 mV that is between 0.01% and 1% of local electron temperature. The solitary waves are associated with quasi‐Maxwellian ion velocity distribution functions, and their plasma frame velocities are comparable with ion thermal speed and well below electron thermal speed. We argue that the solitary waves of positive polarity are slow electron holes and estimate the time scale of their acceleration, which occurs due to interaction with ions, to be of the order of one second. The observation of slow electron holes indicates that their lifetime was shorter than the acceleration time scale. We argue that multi‐spacecraft interferometry applied previously to these solitary waves is not applicable because of their too‐short spatial scales. The source of the slow electron holes and the role in electron‐ion energy exchange remain to be established.

show abstract

Section: Data and Case Studiessupporting

confidence: 80%

Slow Electron Holes in the Earth's Magnetosheath

Shaikh,

Vasko,

Hutchinson

et al. 2024

JGR Space Physics

View full text Add to dashboard Cite

show abstract

“…In order to determine the electric potential from

\vec{E}

of the ESW, the propagation direction must be known. Single‐spacecraft timing (Steinvall et al., 2022) fails, since the magnetic field (and hence the wave propagation direction) is mainly along the shorter axial probes, resulting in an unmeasurable time lag. The ESWs are not observed by all four spacecraft, so we cannot use multi‐spacecraft timing to determine their velocity.…”

Section: Observationsmentioning

confidence: 99%

Waves in Magnetosheath Jets—Classification and the Search for Generation Mechanisms Using MMS Burst Mode Data

et al. 2023

Self Cite

View full text Add to dashboard Cite

Magnetosheath jets are localized dynamic pressure enhancements in the magnetosheath. We make use of the high time resolution burst mode data of the Magnetospheric Multiscale mission for an analysis of waves in plasmas associated with three magnetosheath jets. We find both electromagnetic and electrostatic waves over the frequency range from 0 to 4 kHz that can be probed by the instruments on board the MMS spacecraft. At high frequencies we find electrostatic solitary waves, electron acoustic waves, and whistler waves. Electron acoustic waves and whistler waves show the typical properties expected from theory assuming approximations of a homogeneous plasma and linearity. In addition, 0.2 Hz waves in the magnetic field, 1 Hz electromagnetic waves, and lower hybrid waves are observed. For these waves the approximation of a homogeneous plasma does not hold anymore and the observed waves show properties from several different basic wave modes. In addition, we investigate how the various types of waves are generated. We show evidence that, the 1 Hz waves are connected to gradients in the density and magnetic field. The whistler waves are generated by a butterfly‐shaped pitch‐angle distribution and the electron acoustic waves by a cold electron population. The lower hybrid waves are probably generated by currents at the boundary of the jets. As for the other waves we can only speculate about the generation mechanism due to limitations of the instruments. Studying waves in jets will help to address the microphysics in jets which can help to understand the evolution of jets better.

show abstract

“…Unfortunately, the E80 interferometry technique is restricted to the spin plane, so we cannot use it to get the axial component of the wave vector. Other quantities can be timed in the axial direction, such as the potential measured at probes 5 and 6, but such timing is often unreliable (Steinvall et al., 2022).…”

Section: D Wave Vector Determination Using Spin‐plane Interferometrymentioning

confidence: 99%

“…For electrostatic waves measured by MMS, one can apply interferometry on both the probe potentials or electric fields. Using synthetic data, Steinvall et al (2022) found that one particular electric field configuration, what they call "diagonal electric field" and what we will call E80 electric field, is the most reliable quantity to apply interferometry on. In order to explain the E80 interferometry, we show in Figure 4 a schematic of MMS in the spin plane, using probes 2 and 4 we calculate the electric field E 42 , and using probes 3 and 1 we calculate the electric field E 13 .…”

Section: Spin-plane Wave Vector Determinationmentioning

confidence: 99%

Short‐Wavelength Electrostatic Wave Measurement Using MMS Spacecraft

2023

Self Cite

View full text Add to dashboard Cite

Determination of the wave mode of short‐wavelength electrostatic waves along with their generation mechanism requires reliable measurement of the wave electric field. We show that for such waves the electric field measured by Magnetospheric MultiScale becomes unreliable when the wavelength is close to the probe‐to‐probe separation. We develop a method, based on spin‐plane interferometry, to reliably determine the full three‐dimensional wave vector of the observed waves. We test the method on synthetic data and then apply it to ion acoustic wave bursts measured in the solar wind. By studying the statistical properties of ion acoustic waves in the solar wind, we retrieve the known results that the wave propagation is predominantly field aligned. We also determine the wavelength of the waves. We find that the nominal value is around 100 m, which when normalized to the Debye length corresponds to scales between 10 and 20 Debye lengths.

show abstract

On the Applicability of Single‐Spacecraft Interferometry Methods Using Electric Field Probes

Cited by 7 publications

References 49 publications

Slow Electron Holes in the Earth's Magnetosheath

Slow Electron Holes in the Earth's Magnetosheath

Waves in Magnetosheath Jets—Classification and the Search for Generation Mechanisms Using MMS Burst Mode Data

Short‐Wavelength Electrostatic Wave Measurement Using MMS Spacecraft

Contact Info

Product

Resources

About