Multi-zone non-thermal radiative model for stellar bowshocks

Palacio, Santiago; Bosch‐Ramon, V.; Müller, Ana L.; Romero, Gustavo E.

doi:10.1051/0004-6361/201833321

Cited by 23 publications

(50 citation statements)

References 47 publications

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“…Our estimate of the IC X-ray emission is consistent with the upper limit reported in Sec. 3.3, but is in dis-agreement with previous and more optimistic estimates reported in the literature (e.g., López-Santiago et al 2012;Pereira et al 2016;del Palacio et al 2018). The main reason for that is the different choice of the parameter η e , which in these previous works was assumed to be equal to η e ≈ 0.1, which implicitly implies that wind termination shocks were assumed to be much more effective than SNR shocks in accelerating electrons.…”

Section: Expected X-ray Emission From the Bow Shocksupporting

confidence: 92%

“…so the question arises whether magnetic fields of the order of hundreds of µG could be found at wind termination shocks, and/or whether electrons can be accelerated there beyond 10 TeV. del Palacio et al (2018) noticed that such large values of the magnetic field at the shock are unlikely to be of stellar origin, but require some form of in situ amplification mechanism. One way to estimate the value of the amplified magnetic field is to persist with the analogy with SNR shocks.…”

Section: Maximum Electron Energymentioning

confidence: 99%

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Runaway O-star Bow Shocks as Particle Accelerators? The Case of AE Aur Revisited

Rangelov

Montmerle

Federman

et al. 2019

ApJ

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We present results of our Chandra/ACIS observations of the field centered on the fast, runaway O star AE Aur and its bow shock. Previous XMM-Newton observations revealed an X-ray "blob" near the IR arc tracing the bow shock, possibly a nonthermal source consistent with models of Inverse Compton scattering of dust IR photons by electrons accelerated at the shock. The new, subarcsecond resolution Chandra data, while confirming the presence of the XMM-Newton source, clearly indicate that the latter is neither extended nor coincident with the IR arc and strongly suggest it is a background AGN. Motivated by results published for the bow shock of BD+43 • 3654, we extended our study to the radio domain, by analyzing archival EVLA data. We find no radio emission from the AE Aur bow shock either. The corresponding upper limits for the absorbed (unabsorbed) X-ray flux of 5.9(7.8) × 10 −15 erg cm −2 s −1 (3σ) and, in the radio range, of 2 mJy (1.4 GHz), and 0.4 mJy (5.0 GHz), are used to put constraints on model predictions for particle acceleration within the bow shock. In the "classical" framework of Diffusive Shock Acceleration, we find that the predicted X-ray and radio emission by the bow shock is at least two orders of magnitude below the current upper limits, consistent with the systematic non-detections of up to 60 stellar bow shocks. The only exception so far remains that of BD+43 • 3654, probably the result of its very large mass-loss rate among runaway O stars.

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Section: Expected X-ray Emission From the Bow Shocksupporting

confidence: 92%

Section: Maximum Electron Energymentioning

confidence: 99%

Runaway O-star Bow Shocks as Particle Accelerators? The Case of AE Aur Revisited

Rangelov

Montmerle

Federman

et al. 2019

ApJ

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“…Recently, other types of stellar sources have been proposed as possible gamma-ray emitters, and different scenarios were analyzed. In addition to the well-studied microquasars (Romero et al 2003), colliding-wind binaries (Benaglia & Romero 2003), Herbig Haro objects, young stellar objects (YSO), (Bosch-Ramon et al 2010;Araudo et al 2007;Rodríguez-Kamenetzky et al 2019), A&A 642, A136 (2020) and stellar bow shocks (Benaglia et al 2010;del Valle & Pohl 2018;del Palacio et al 2018) are capable of producing gammarays. A signature of high-energy emission is nonthermal radio emission because particles from the same population are likely to be involved in processes at both energy ranges, at the radio through synchrotron process, and at VHE emission through inverse-Compton scattering.…”

Section: Introductionmentioning

confidence: 99%

Cygnus survey with the Giant Metrewave Radio Telescope at 325 and 610 MHz: the catalog

Benaglia

Ishwara‐Chandra

Intema

et al. 2020

A&A

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Context. Observations at the radio continuum band below the gigahertz band are key when the nature and properties of nonthermal sources are investigated because their radio radiation is strongest at these frequencies. The low radio frequency range is therefore the best to spot possible counterparts to very high-energy (VHE) sources: relativistic particles of the same population are likely to be involved in radio and high-energy radiation processes. Some of these counterparts to VHE sources can be stellar sources. Aims. The Cygnus region in the northern sky is one of the richest in this type of sources that are potential counterparts to VHE sources. We surveyed the central ∼15 sq deg of the Cygnus constellation at the 325 and 610 MHz bands with angular resolutions and sensitivities of 10″ and 6″, and 0.5 and 0.2 mJy beam−1, respectively. Methods. The data were collected during 172 h in 2013–2017, using the Giant Metrewave Radio Telescope with 32 MHz bandwidth, and were calibrated using the SPAM routines. The source extraction was carried out with the PyBDSF tool, followed by verification through visual inspection of every putative catalog candidate source in order to determine its reliability. Results. In this first paper we present the catalog of sources, consisting of 1048 sources at 325 MHz and 2796 sources at 610 MHz. By cross-matching the sources from both frequencies with the objects of the SIMBAD database, we found possible counterparts for 143 of them. Most of the sources from the 325-MHz catalog (993) were detected at the 610 MHz band, and their spectral index α was computed adopting S(ν) ∝ να. The maximum of the spectral index distribution is at α = −1, which is characteristic of nonthermal emitters and might indicate an extragalactic population.

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“…El modelo y resultados aquí presentados corresponden al trabajo publicado en [98]. La mayoría de los modelos de emisión NT en BSs estelares previamente presentados en la literatura eran del tipo one-zone (ver Sec.…”

Section: Modelounclassified

“…Figura 3.3. Esquema (no a escala) del modelo considerado en [98]. A pesar de la representación de los ejes, en nuestros cálculos la posición (0, 0) corresponde a la ubicación de la estrella.…”

Section: Geometríaunclassified

Radiación no térmica asociada a estrellas de gran masa

Palacio

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Uno de los principales desafíos de la astrofísica de altas energías es entender las conexiones que subyacen entre los rayos cósmicos y la radiación no térmica (NT), en particular, en la banda de los rayos γ. Hay extensa evidencia observacional que vincula a las estrellas de gran masa con procesos no térmicos, y en particular se ha establecido que pueden jugar un rol importante –o incluso dominante– en la aceleración de rayos cósmicos Galácticos. En esta Tesis nos hemos abocado a investigar la emisión NT producida en sistemas con estrellas de gran masa y, de forma indirecta, la aceleración de partículas relativistas en estos objetos. Hemos desarrollado herramientas para avanzar en la dirección de dar respuestas a interrogantes tales como cuál es la eficiencia de aceleración de rayos cósmicos en choques desencadenados por vientos estelares, bajo qué condiciones los sistemas con estrellas de gran masa pueden ser emisores de rayos γ, y cuál es la intensidad y topología de los campos magnéticos en estos escenarios. El abordaje con que lo hemos hecho consiste principalmente en la modelización de los procesos no térmicos que ocurren en sistemas con estrellas de gran masa, entre ellos estrellas runaway (fugitivas) con bow-shocks (choques de proa), sistemas binarios con colisión de vientos y binarias de rayos γ. Estos modelos requieren del desarrollo de códigos numéricos de relativa complejidad para estimar la emisión esperada en los distintos escenarios a lo largo de todo el espectro electromagnético. En particular, hemos realizado dos tipos de modelos, dependiendo de la física del escenario analizado. Por un lado, modelos one-zone altamente simplificados, útiles para captar la física relevante a primer orden en fuentes no térmicas puntuales (no resueltas). Por otro lado, modelos multi-zona más detallados que contemplan la estructura del emisor, por lo que permiten producir mapas de emisión comparables con los observados en fuentes resueltas. Dichos modelos son versátiles y pueden utilizarse para estudiar otras fuentes no térmicas; en particular, en esta Tesis mostramos una aplicación para el estudio de blazares. Mediante la aplicación de los modelos al estudio de fuentes concretas, hemos determinado o acotado parámetros libres de los mismos, lo cual ha servido para realizar predicciones cuantitativas que serán verificables con futuras observaciones. En esta línea, también se ha participado en la elaboración de cerca de una decena de propuestas observacionales ya aprobadas, cuyo impacto dependerá de lo que revelen los resultados observacionales en un futuro cercano. Las fuentes observadas incluyen burbujas estelares (aisladas y en colisión), bow-shocks estelares, y binarias con colisión de vientos. Finalmente, resaltamos que la generalización y extrapolación de los resultados de observaciones específicas permitirán abordar estudios poblacionales y obtener conclusiones más generales en cuanto a la radiación NT producida en sistemas con estrellas de gran masa.

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Multi-zone non-thermal radiative model for stellar bowshocks

Cited by 23 publications

References 47 publications

Runaway O-star Bow Shocks as Particle Accelerators? The Case of AE Aur Revisited

Runaway O-star Bow Shocks as Particle Accelerators? The Case of AE Aur Revisited

Cygnus survey with the Giant Metrewave Radio Telescope at 325 and 610 MHz: the catalog

Radiación no térmica asociada a estrellas de gran masa

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