Interplanetary dust fluxes observed with Parker Solar Probe
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https://hdl.handle.net/10037/19193Date
2020-06-29Type
Master thesisMastergradsoppgave
Author
Henriksen, Emil GorsethAbstract
The mission Parker Solar Probe (PSP) provides a new opportunity to make
in-situ measurements of dust impacts closer to the Sun than ever before,
eventually going as close as ∼ 10 solar radii or ∼ 0.05 AU. PSP can measure
dust impacts from monopole measurements of the spacecraft’s electric potential
to one of its antennas using its FIELDS instrument. In this work impact rates
data is compared to model calculations of dust flux at the spacecraft. The
measurements are best described by dust particles forming inside of the PSP’s
orbit. The particles then move in hyperbolic orbits away from the Sun because
they are repelled by the radiation pressure force. The dust particles can be
pushed outward when the ratio of radiation pressure to gravity force exceeds
0.5. This ratio is often denoted as the beta value and the particles in unbound
orbits as beta meteoroids.
In this thesis the dust impact rates measured by PSP during its second orbit
are compared to calculated dust fluxes. The flux is influenced by the distance
from the Sun, where the particles form, and their radiation pressure to gravity
ratio (“beta value”). The finding of the range of these parameters result in well
described impact rates. The radiation pressure to gravity ratio is found to be
generally higher than previous studies. This suggests that PSP measures highly
absorbing particles which could be dust particles freshly released from comets.
An alternative suggestion is that the particles are not initially on circular orbits,
but rather on highly elliptical orbits which will lead to a higher observed
radiation pressure to gravity ratio. Three selected signals from monopole
measurements are analyzed to derive dust particle parameters such as radiation
pressure to gravity ratio and production distance. The signals are in agreement
with beta meteoroids which are produced within 13 solar radii and with a
radiation pressure to gravity ratio of above 1. It is shown that for the assumed
dust impact signals an increase in production distance has to be met with an
increase in the radiation pressure to gravity ratio. Similarly, if the particle is
to be produced closer to the Sun it must have a smaller radiation pressure to
gravity ratio.
Publisher
UiT Norges arktiske universitetUiT The Arctic University of Norway
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