Abstrakti
Since the mid-1980s the shock-in-jet model has been the preferred
paradigm to explain radio-band flaring in blazar jets. We describe our
radiative transfer model incorporating relativistically-propagating
shocks, and illustrate how the 4.8, 8, and 14.5 GHz linear polarization
and total flux density data from the University of Michigan monitoring
program, in combination with the model, constrain jet flow conditions
and shock attributes. Results from strong Fermi-era flares in 4 blazars
with widely-ranging properties are presented. Additionally, to
investigate jet evolution on decadal time scales we analyze 3 outbursts
in OT 081 spanning nearly 3 decades and find intrinsic changes
attributable to flow changes at a common spatial location, or,
alternatively, to a change in the jet segment viewed. The model's
success in reproducing these data supports a scenario in which
relativistic shocks compress a plasma with an embedded passive,
initially-turbulent magnetic field, with additional ordered magnetic
field components, one of which may be helical.
Alkuperäiskieli | Englanti |
---|---|
Artikkeli | 35 |
Sivut | 1-10 |
Sivumäärä | 10 |
Julkaisu | Galaxies |
Vuosikerta | 4 |
Numero | 4 |
DOI - pysyväislinkit | |
Tila | Julkaistu - jouluk. 2016 |
OKM-julkaisutyyppi | A1 Alkuperäisartikkeli tieteellisessä aikakauslehdessä |
Sormenjälki
Sukella tutkimusaiheisiin 'Radiative Transfer Modeling of Radio-Band Linear Polarization Observations as a Probe of the Physical Conditions in the Jets of γ-Ray Flaring Blazars'. Ne muodostavat yhdessä ainutlaatuisen sormenjäljen.Laitteet
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Metsähovin radiotutkimusasema
Tammi, J. (Manager)
Sähkötekniikan korkeakouluLaitteistot/tilat: Facility