Covariant polarized radiative transfer on cosmological scales for investigating large-scale magnetic field structures

Chan, Jennifer Y H; Wu, Kinwah; On, Alvina Y. L.; Barnes, David J.; McEwen, Jason D.; Kitching, Thomas D.

doi:10.1093/mnras/sty3498

Cited by 11 publications

(10 citation statements)

References 97 publications

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“…This may contribute to the growth of cosmological magnetic fields (Kronberg 2016;Durrer & Neronov 2013) as might be detected by e.g. co-variant polarised radiative transfer methods (Chan et al 2019). Cosmic rays may also deposit energy to heat and ionise matter at high flow altitudes (Owen et al 2019a) possibly reaching into the circumgalactic and/or intergalactic medium, and this may contribute to the progression of cosmic pre-heating and reionisation (e.g.…”

Section: Astrophysical Implicationsmentioning

confidence: 99%

A hydrodynamical study of outflows in starburst galaxies with different driving mechanisms

Owen

et al. 2020

Monthly Notices of the Royal Astronomical Society

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Outflows from starburst galaxies can be driven by thermal pressure, radiation and cosmic rays. We present an analytic phenomenological model that accounts for these contributions simultaneously to investigate their effects on the hydrodynamical properties of outflows. We assess the impact of energy injection, wind opacity, magnetic field strength and the mass of the host galaxy on flow velocity, temperature, density and pressure profiles. For an M82-like wind, a thermally-dominated driving mechanism is found to deliver the fastest and hottest wind. Radiation-driven winds in typical starburst-galaxy configurations are unable to attain the higher flow velocities and temperatures associated with thermal and cosmic ray-driven systems, leading to higher wind densities which would be more susceptible to cooling and fragmentation at lower altitudes. High opacity winds are more sensitive to radiative driving, but terminal flow velocities are still lower than those achieved by other driving mechanisms at realistic opacities. We demonstrate that variations in the outflow magnetic field can influence its coupling with cosmic rays, where stronger fields enable greater streaming but less driving near the base of the flow, instead with cosmic rays redirecting their driving impact to higher altitudes. The gravitational potential is less important in M82-like wind configurations, and substantial variations in the flow profiles only emerge at high altitude in massive haloes. This model offers a more generalised approach to examine the large scale hydrodynamical properties for a wide variety of starburst galaxies.

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Section: Astrophysical Implicationsmentioning

confidence: 99%

A hydrodynamical study of outflows in starburst galaxies with different driving mechanisms

Owen

et al. 2020

Monthly Notices of the Royal Astronomical Society

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“…We model the propagation of 𝛾-rays from populations of SFGs to form an EGB model at 𝑧 = 0 using a cosmological radiative transfer approach, which ensures conservation of photon number and phase space volume (Fuerst & Wu 2004;Chan et al 2019). This accounts for pair-production processes arising between 𝛾-rays and soft, intergalactic extra-galactic background light (EBL) photons, and the subsequent inverse Compton scattering of CMB photons to 𝛾-ray energies by the produced pairs (the cascade effect), using the semi-analytic EBL model of Inoue et al (2013).…”

Section: Cosmological 𝛾-Ray Propagationmentioning

confidence: 99%

The extragalactic $γ$-ray background: imprints from the physical properties and evolution of star-forming galaxy populations

Owen,

Kong,

Lee

2021

Preprint

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Star-forming galaxies (SFGs) are expected to harbour an abundant reservoir of cosmic rays (CRs). At GeV energies, these CRs can undergo hadronic interactions with interstellar gases to produce 𝛾-rays, and the unresolved 𝛾-ray emission from populations of SFGs form a component of the extragalactic 𝛾-ray background (EGB). In this work, we investigate the contribution to the 0.01 -50 GeV EGB from SFG populations located up to redshift 𝑧 = 3. We consider their redshift evolution and variations in their physical properties, and model how this affects their contribution to the EGB. We find this is dominated by starbursts, while the contribution from main sequence SFGs is marginal at all energies. We also demonstrate that most of the 𝛾-ray contribution from SFGs emanates from low mass galaxies, with over 80 per cent of the emission originating from galaxies with stellar masses below 10 8 M . We show that the EGB at different energies captures different stages of the evolution of the source galaxies. At 0.01 GeV, the emission is dominated by galaxies at the noon of cosmic star-formation, around 𝑧 ∼ 2, however higher energy 𝛾-rays are instead mainly contributed from low mass starburst populations at higher redshifts, ∼ 700 Myr earlier. The redshift distributions of the EGB sources at different energies imprint intensity signatures at different angular scales, allowing their contribution to be distinguished using analyses of small-scale EGB intensity anisotropies. We show that the EGB is sensitive to the evolution of low mass populations of galaxies, particularly around 𝑧 ∼ 2 − 2.5, and that it provides a new means to probe the engagement of CRs in these galaxies before and during the high noon of cosmic star-formation.

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“…(e.g. Chan et al 2019) 5 where all quantities are Lorentz invariant, i.e. I 𝛾 = 𝐼 𝛾 /𝑣 3 for 𝐼 𝛾 as the local 'proper' intensity (such that, in practice, co-moving absorption 𝛼 𝛾𝛾 and emission 𝑗 𝛾 functions are used for the attenuation and cascade re-emission of 𝛾-rays respectively, as well as co-moving frequency 𝜈), and d𝑠/d𝑧 for a flat Friedmann-Robertson-Walker (FRW) Universe is given by…”

Section: Cosmological 𝛾-Ray Radiative Transfermentioning

confidence: 99%

Characterising the signatures of star-forming galaxies in the extra-galactic $γ$-ray background

Owen,

Lee,

Kong

2021

Preprint

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Galaxies experiencing intense star-formation episodes are expected to be rich in energetic cosmic rays (CRs). These CRs undergo hadronic interactions with the interstellar gases of their host to drive 𝛾-ray emission, which has already been detected from several nearby starbursts. Unresolved 𝛾-ray emission from more distant star-forming galaxies (SFGs) is expected to contribute to the extra-galactic 𝛾-ray background (EGB). However, despite the wealth of highquality all-sky data from the Fermi-LAT 𝛾-ray space telescope collected over more than a decade of operation, the exact contribution of such SFGs to the EGB remains unsettled. We investigate the high-energy 𝛾-ray emission from SFGs up to redshift 𝑧 = 3 above a GeV, and assess the contribution they can make to the EGB. We show the 𝛾-ray emission spectrum from a SFG population can be determined from just a small number of key parameters, from which we model a range of possible EGB realisations. We demonstrate that populations of SFGs leave anisotropic signatures in the EGB, and that these can be accessed using the spatial power spectrum. Moreover, we show that such signatures will be accessible with ongoing operation of current 𝛾-ray instruments, and detection prospects will be greatly improved by the next generation of 𝛾-ray observatories, in particular the Cherenkov Telescope Array.

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Covariant polarized radiative transfer on cosmological scales for investigating large-scale magnetic field structures

Cited by 11 publications

References 97 publications

A hydrodynamical study of outflows in starburst galaxies with different driving mechanisms

A hydrodynamical study of outflows in starburst galaxies with different driving mechanisms

The extragalactic $γ$-ray background: imprints from the physical properties and evolution of star-forming galaxy populations

Characterising the signatures of star-forming galaxies in the extra-galactic $γ$-ray background

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