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1. The cosmic-ray staircase: the outcome of the cosmic-ray acoustic instability

   https://doi.org/10.1093/mnras/stac1123  

   Tsung, Tsun Hin Navin; Oh, S. Peng; Jiang, Yan-Fei (April 2022, Monthly Notices of the Royal Astronomical Society)

   ABSTRACT Recently, cosmic rays (CRs) have emerged as a leading candidate for driving galactic winds. Small-scale processes can dramatically affect global wind properties. We run two-moment simulations of CR streaming to study how sound waves are driven unstable by phase-shifted CR forces and CR heating. We verify linear theory growth rates. As the sound waves grow non-linear, they steepen into a quasi-periodic series of propagating shocks; the density jumps at shocks create CR bottlenecks. The depth of a propagating bottleneck depends on both the density jump and its velocity; ΔPc is smaller for rapidly moving bottlenecks. A series of bottlenecks creates a CR staircase structure, which can be understood from a convex hull construction. The system reaches a steady state between growth of new perturbations, and stair mergers. CRs are decoupled at plateaus, but exert intense forces and heating at stair jumps. The absence of CR heating at plateaus leads to cooling, strong gas pressure gradients and further shocks. If bottlenecks are stationary, they can drastically modify global flows; if their propagation times are comparable to dynamical times, their effects on global momentum and energy transfer are modest. The CR acoustic instability is likely relevant in thermal interfaces between cold and hot gas, as well as galactic winds. Similar to increased opacity in radiative flows, the build-up of CR pressure due to bottlenecks can significantly increase mass outflow rates, by up to an order of magnitude. It seeds unusual forms of thermal instability, and the shocks could have distinct observational signatures, on ∼kpc scales. 

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2. Cosmic ray feedback in the FIRE simulations: constraining cosmic ray propagation with GeV gamma ray emission

   https://doi.org/10.1093/mnras/stz1895  

   Chan, T K; Kereš, D; Hopkins, P F; Quataert, E; Su, K-Y; Hayward, C C; Faucher-Giguère, C-A (July 2019, Monthly Notices of the Royal Astronomical Society)

   Abstract We present the implementation and the first results of cosmic ray (CR) feedback in the Feedback In Realistic Environments (FIRE) simulations. We investigate CR feedback in non-cosmological simulations of dwarf, sub-L⋆ starburst, and L⋆ galaxies with different propagation models, including advection, isotropic and anisotropic diffusion, and streaming along field lines with different transport coefficients. We simulate CR diffusion and streaming simultaneously in galaxies with high resolution, using a two moment method. We forward-model and compare to observations of γ-ray emission from nearby and starburst galaxies. We reproduce the γ-ray observations of dwarf and L⋆ galaxies with constant isotropic diffusion coefficient κ ∼ 3 × 1029 cm2 s−1. Advection-only and streaming-only models produce order-of-magnitude too large γ-ray luminosities in dwarf and L⋆ galaxies. We show that in models that match the γ-ray observations, most CRs escape low-gas-density galaxies (e.g. dwarfs) before significant collisional losses, while starburst galaxies are CR proton calorimeters. While adiabatic losses can be significant, they occur only after CRs escape galaxies, so they are only of secondary importance for γ-ray emissivities. Models where CRs are “trapped” in the star-forming disk have lower star formation efficiency, but these models are ruled out by γ-ray observations. For models with constant κ that match the γ-ray observations, CRs form extended halos with scale heights of several kpc to several tens of kpc. 

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3. Cosmic-Ray Extremely Distributed Observatory

   https://doi.org/10.3390/sym12111835  

   Homola, Piotr; Beznosko, Dmitriy; Bhatta, Gopal; Bibrzycki, Łukasz; Borczyńska, Michalina; Bratek, Łukasz; Budnev, Nikolay; Burakowski, Dariusz; Alvarez-Castillo, David E.; Almeida Cheminant, Kevin; et al (November 2020, Symmetry)

   null (Ed.)

   The Cosmic-Ray Extremely Distributed Observatory (CREDO) is a newly formed, global collaboration dedicated to observing and studying cosmic rays (CR) and cosmic-ray ensembles (CRE): groups of at least two CR with a common primary interaction vertex or the same parent particle. The CREDO program embraces testing known CR and CRE scenarios, and preparing to observe unexpected physics, it is also suitable for multi-messenger and multi-mission applications. Perfectly matched to CREDO capabilities, CRE could be formed both within classical models (e.g., as products of photon–photon interactions), and exotic scenarios (e.g., as results of decay of Super-Heavy Dark Matter particles). Their fronts might be significantly extended in space and time, and they might include cosmic rays of energies spanning the whole cosmic-ray energy spectrum, with a footprint composed of at least two extensive air showers with correlated arrival directions and arrival times. As the CRE are predominantly expected to be spread over large areas and, due to the expected wide energy range of the contributing particles, such a CRE detection might only be feasible when using all available cosmic-ray infrastructure collectively, i.e., as a globally extended network of detectors. Thus, with this review article, the CREDO Collaboration invites the astroparticle physics community to actively join or to contribute to the research dedicated to CRE and, in particular, to pool together cosmic-ray data to support specific CRE detection strategies. 

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4. Cosmic Neutrinos and the Cosmic-Ray Accelerator TXS 0506+056

   https://doi.org/10.22323/1.358.0021  

   Halzen, Francis (January 2020, Pos proceedings of science)
5. Cosmic-ray upscattered inelastic dark matter

   https://doi.org/10.1103/PhysRevD.104.076020  

   Bell, Nicole F.; Dent, James B.; Dutta, Bhaskar; Ghosh, Sumit; Kumar, Jason; Newstead, Jayden L.; Shoemaker, Ian M. (October 2021, Physical Review D)