Effects of non-continuous inverse Compton cooling in blazars
Jul 25, 20238 pages
Published in:
- PoS ICRC2023 (2023) 645
Contribution to:
- , 645
- ICRC2023
- Published: Jul 25, 2023
DOI:
Citations per year
Abstract: (SISSA)
Flaring states of blazars are ideally suited to study the extreme physics of relativistic outflows. A thorough understanding of particle acceleration and cooling mechanisms operating in blazar jetscan be achieved via physical modeling of varying multi-band flaring emission from radio up to gamma-ray range. The majority of the numerical codes developed for this task use a simplified continuous-loss description for the inverse Compton particle cooling. Such an approximation is however no longer valid in the Klein-Nishina (KN) regime, as particles suffer large relative jumps in energy. In our study, we explore the importance of non-continuous (discrete) Compton cooling losses and their effect on the blazar electron spectrum and broad-band spectral energy distribution (SED) for typical physical conditions during blazar gamma-ray flares. We solve numerically the full transport equation that takes into account large relative jumps in energy, and simulate the time-dependent electron spectrum and SED for the conditions of extreme flares of the Flat Spectrum Radio Quasar (FSRQ) 3C 279. We find that non-continuous cooling can significantly modify the shape of the electron spectrum, resulting in notable differences of up to a factor of 1.35 – 2 in the corresponding SEDs during both low and flaring states.References(14)
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