JOVIAN AND EXOPLANET AURORAL RADIO EMISSION PROFILE IN THE LOW-FREQUENCY RANGE
Earth and giant planets in our Solar System are known to possess an internal magnetic eld and a thick atmosphere that are capable of producing non- thermal low-frequency radio emissions through the Cyclotron Maser Instabili- ty (CMI) mechanism. Particularly for Jupiter, interactions with its sate...
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| Format: | Final Project |
| Language: | Indonesia |
| Subjects: | |
| Online Access: | https://digilib.itb.ac.id/gdl/view/60917 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Earth and giant planets in our Solar System are known to possess an internal
magnetic eld and a thick atmosphere that are capable of producing non-
thermal low-frequency radio emissions through the Cyclotron Maser Instabili-
ty (CMI) mechanism. Particularly for Jupiter, interactions with its satellites
can also in
uence the probability of detecting radio emissions. In line wi-
th this analogy, such radio emissions are expected to be detected from other
exoplanetary systems, especially Jupiter-like exoplanets. This thesis focuses
on planetary radio emissions in our Solar System and how its detection me-
chanism can be applied for exoplanetary systems. It is also expected to give
informations about the physical properties of exoplanets, not limited to only
conrming its existence.
Using ExPRES (Exoplanetary and Planetary Radio Emission Simulator)
code, we explain how and what are the physical properties of an exoplanet
system that can be inferred from observed dynamic spectra based on previ-
ously made assumptions of the radio emission source(s). Simulated dynamic
spectra from ExPRES show incredibly well conformity with observational da-
ta from Nancay Decameter Array (NDA), Voyager 1 & 2, and Juno that have
been carried before, so it is considered applicable for exoplanetary studies and
detections. We show and analyze the shape and temporal modulations from si-
mulated dynamic spectra to draw out physical information of the exoplanetary
system through radio observations. This information includes magnetic eld
strength, orbital inclination, rotational and orbital periods, and the magnetic
eld tilt and oset. This approach is expected to be a proper framework for
future detections of radio emissions from exoplanetary systems.
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