115 research outputs found
Cosmic Ray propagation in sub-Alfvenic magnetohydrodynamic turbulence
This work has the main objective to provide a detailed investigation of
cosmic ray propagation in magnetohydrodynamic turbulent fields generated by
forcing the fluid velocity field at large scales. It provides a derivation of
the particle mean free path dependences in terms of the turbulence level
described by the Alfv\'enic Mach number and in terms of the particle rigidity.
We use an upgrade version of the magnetohydrodynamic code {\tt RAMSES} which
includes a forcing module and a kinetic module and solve the Lorentz equation
for each particle. The simulations are performed using a 3 dimension periodical
box in the test-particle and magnetostatic limits. The forcing module is
implemented using an Ornstein-Uhlenbeck process. An ensemble average over a
large number of particle trajectories is applied to reconstruct the particle
mean free paths. We derive the cosmic ray mean free paths in terms of the
Alfv\'enic Mach numbers and particle reduced rigidities in different turbulence
forcing geometries. The reduced particle rigidity is where
is the particle Larmor radius and is the simulation box length related to
the turbulence coherence or injection scale by . We
have investigated with a special attention compressible and solenoidal forcing
geometries. We find that compressible forcing solutions are compatible with the
quasi-linear theory or more advanced non-linear theories which predict a
rigidity dependence as or . Solenoidal forcing
solutions at least at low or moderate Alfv\'enic numbers are not compatible
with the above theoretical expectations and require more refined arguments to
be interpreted. It appears especially for Alfv\'enic Mach numbers close to one
that the wandering of field lines controls perpendicular mean free path
solutions whatever the forcing geometry.Comment: 15 pages, 18 figures. Accepted for publication in section 2.
Astrophysical processes of Astronomy and Astrophysic
MARCOS, a numerical tool for the simulation of multiple time-dependent non-linear diffusive shock acceleration
We present a new code aimed at the simulation of diffusive shock acceleration
(DSA), and discuss various test cases which demonstrate its ability to study
DSA in its full time-dependent and non-linear developments. We present the
numerical methods implemented, coupling the hydrodynamical evolution of a
parallel shock (in one space dimension) and the kinetic transport of the
cosmic-rays (CR) distribution function (in one momentum dimension), as first
done by Falle. Following Kang and Jones and collaborators, we show how the
adaptive mesh refinement technique (AMR) greatly helps accommodating the
extremely demanding numerical resolution requirements of realistic (Bohm-like)
CR diffusion coefficients. We also present the paral lelization of the code,
which allows us to run many successive shocks at the cost of a single shock,
and thus to present the first direct numerical simulations of linear and
non-linear multiple DSA, a mechanism of interest in various astrophysical
environments such as superbubbles, galaxy clusters and early cosmological
flows.Comment: accepted for publication in MNRAS by the Royal Astronomical Society
and Blackwell Publishin
Cosmic-ray acceleration in young protostars
The main signature of the interaction between cosmic rays and molecular
clouds is the high ionisation degree. This decreases towards the densest parts
of a cloud, where star formation is expected, because of energy losses and
magnetic effects. However recent observations hint to high levels of ionisation
in protostellar systems, therefore leading to an apparent contradiction that
could be explained by the presence of energetic particles accelerated within
young protostars. Our modelling consists of a set of conditions that has to be
satisfied in order to have an efficient particle acceleration through the
diffusive shock acceleration mechanism. We find that jet shocks can be strong
accelerators of protons which can be boosted up to relativistic energies.
Another possibly efficient acceleration site is located at protostellar
surfaces, where shocks caused by impacting material during the collapse phase
are strong enough to accelerate protons. Our results demonstrate the
possibility of accelerating particles during the early phase of a
proto-Solar-like system and can be used as an argument to support available
observations. The existence of an internal source of energetic particles can
have a strong and unforeseen impact on the star and planet formation process as
well as on the formation of pre-biotic molecules.Comment: Accepted by Astronomy and Astrophysic
Shape and evolution of wind-blown bubbles of massive stars: on the effect of the interstellar magnetic field
The winds of massive stars create large (>10 pc) bubbles around their
progenitors. As these bubbles expand they encounter the interstellar coherent
magnetic field which, depending on its strength, can influence the shape of the
bubble. We wish to investigate if, and how much, the interstellar magnetic
field can contribute to the shape of an expanding circumstellar bubble around a
massive star. We use the MPI-AMRVAC code to make magneto-hydrodynamical
simulations of bubbles, using a single star model, combined with several
different field strengths: B = 5, 10, and 20 muG for the interstellar magnetic
field. This covers the typical field strengths of the interstellar magnetic
fields found in the galactic disk and bulge. Furthermore, we present two
simulations that include both a 5 muG interstellar magnetic field and a 10,000
K interstellar medium and two different ISM densities to demonstrate how the
magnetic field can combine with other external factors to influence the
morphology of the circumstellar bubbles. Our results show that low magnetic
fields, as found in the galactic disk, inhibit the growth of the circumstellar
bubbles in the direction perpendicular to the field. As a result, the bubbles
become ovoid, rather than spherical. Strong interstellar fields, such as
observed for the galactic bulge, can completely stop the expansion of the
bubble in the direction perpendicular to the field, leading to the formation of
a tube-like bubble. When combined with a warm, high-density ISM the bubble is
greatly reduced in size, causing a dramatic change in the evolution of
temporary features inside the bubble. The magnetic field of the interstellar
medium can affect the shape of circumstellar bubbles. This effect may have
consequences for the shape and evolution of circumstellar nebulae and supernova
remnants, which are formed within the main wind-blown bubble.Comment: Proposed for acceptance for publication in Astronomy & Astrophysics.
The published version will contain animations of each simulatio
Non-linear Cosmic Ray propagation close to the acceleration site
Recent advances on gamma-ray observations from SuperNova Remnants and
Molecular Clouds offer the possibility to study in detail the properties of the
propagation of escaping Cosmic Rays (CR). However, a complete theory for CR
transport outside the acceleration site has not been developed yet. Two
physical processes are thought to be relevant to regulate the transport: the
growth of waves caused by streaming instability, and possible wave damping
mechanisms that reduce the growth of the turbulence. Only a few attempts have
been made so far to incorporate these mechanisms in the theory of CR diffusion.
In this work we present recent advances in this subject. In particular, we show
results obtained by solving the coupled equations for the diffusion of CRs and
the evolution of Alfven waves. We discuss the importance of streaming
instabilities and wave damping in different ISM phases.Comment: Contribution to the Proceedings of the 34th International Cosmic Ray
Conference (ICRC 2015), The Hague, The Netherland
Embedded star clusters as sources of high-energy cosmic rays: Modelling and constraints
Massive stars are mainly found in stellar associations. These massive star
clusters occur in the heart of giant molecular clouds. The strong stellar wind
activity in these objects generates large bubbles and induces collective
effects that could accelerate particles up to high energy and produce gamma
rays. The best way to input an acceleration origin to the stellar wind
interaction in massive stellar cluster is to observe young massive star
clusters in which no supernova explosion has occurred yet.
This work aims to constrain the part of stellar wind mechanical energy that
is converted into energetic particles using the sensitivity of the ongoing
Fermi/LAT instrument. This work further provides detailed predictions of
expected gamma-ray fluxes in the view of the on-set of the next generation of
imaging atmospheric Cherenkov telescopes.
A one-zone model where energetic particles are accelerated by repeated
interactions with strong supersonic shocks occurring in massive star clusters
was developed. The particle escape from the star cluster and subsequent
interaction with the surrounding dense material and magnetic fields of the HII
region was computed. We applied this model to a selection of eight embedded
star clusters constricted by existing observations. We evaluated the gamma-ray
signal from each object, combining both leptonic and hadronic contributions. We
searched for these emissions in the Fermi/LAT observations in the energy range
from 3 to 300 GeV and compared them to the sensitivity of the Cherenkov
Telescope Array.
No significant gamma-ray emission from these star clusters has been found.
Less than 10% of stellar wind luminosities are supplied to the relativistic
particles. Some clusters even show acceleration efficiency of less than 1%. The
CTA would be able to detect gamma-ray emission from several clusters in the
case of an acceleration efficiency of close to 1%.Comment: accepted for publication in Astronomy&Astrophysic
Non-linear diffusion of cosmic rays escaping from supernova remnants - I. The effect of neutrals
Supernova remnants are believed to be the main sources of galactic Cosmic
Rays (CR). Within this framework, particles are accelerated at supernova
remnant shocks and then released in the interstellar medium. The mechanism
through which CRs are released and the way in which they propagate still remain
open issues. The main difficulty is the high non-linearity of the problem: CRs
themselves excite the magnetic turbulence that confines them close to their
sources. We solve numerically the coupled differential equations describing the
evolution in space and time of the escaping particles and of the waves
generated through the CR streaming instability. The warm ionized and warm
neutral phases of the interstellar medium are considered. These phases occupy
the largest fraction of the disc volume, where most supernovae explode, and are
characterised by the significant presence of neutral particles. The friction
between those neutrals and ions results in a very effective wave damping
mechanism. It is found that streaming instability affects the propagation of
CRs even in the presence of ion-neutral friction. The diffusion coefficient can
be suppressed by more than a factor of over a region of few tens of pc
around the remnant. The suppression increases for smaller distances. The
propagation of GeV particles is affected for several tens of
kiloyears after escape, while TeV particles are affected for few
kiloyears. This might have a great impact on the interpretation of gamma-ray
observations of molecular clouds located in the vicinity of supernova remnants.Comment: Revised to match the version published in MNRA
Bell Instability-Mediated Diffusive Shock Acceleration at Supernova Blast Wave Shock Propagating in the ISM
Supernova blast wave shock is a very important site of cosmic-ray
acceleration. However, the detailed physical process of acceleration, in
particular, non-linear interplay between cosmic-ray streaming and magnetic
field amplification has not been studied under a realistic environment. In this
paper, using a unique and novel numerical method, we study cosmic-ray
acceleration at supernova blast wave shock propagating in the interstellar
medium with well-resolved magnetic field amplification by non-resonant hybrid
instability (or Bell instability). We find that the magnetic field is mildly
amplified under typical ISM conditions that leads to maximum cosmic-ray energy
~30 TeV for supernova remnants with age ~1000 years consistent with gamma-ray
observations. The strength of the amplified magnetic field does not reach
so-called saturation level, because cosmic-ray electric current towards the
shock upstream has finite spatial extent, by which Bell instability cannot
experience many e-folding times.Comment: ApJ accepte
Population synthesis of pulsar wind nebulae and pulsar halos in the Milky Way -- Predicted contributions to the very-high-energy sky
The discovery of extended gamma-ray emission toward a number of middle-aged
pulsars suggests the possibility of long-lived particle confinement beyond the
classical pulsar wind nebula (PWN) stage. How this emerging source class can be
extrapolated to a Galactic population remains unclear. We aim to evaluate how
pulsar halos fit in existing TeV observations, under the assumption that all
middle-aged pulsars develop halos similar to those observed toward the
J0633+1746 or B0656+14 pulsars. We modeled the populations of supernova
remnants, PWNe, and pulsar halos in the Milky Way. The PWN-halo evolutionary
sequence is described in a simple yet coherent framework, and both kinds of
objects are assumed to share the same particle injection properties. We then
assessed the contribution of the different source classes to the
very-high-energy emission from the Galaxy. The synthetic population can be made
consistent with the flux distribution of all known objects, including
unidentified objects, for a reasonable set of parameters. The fraction of the
populations predicted to be detectable in surveys of the Galactic plane with
HESS. and HAWC is then found to be in good agreement with their actual outcome,
with a number of detectable halos ranging from 30 to 80% of the number of
detectable PWNe. Prospects for CTA involve the detection of 250-300 sources in
the Galactic Plane Survey, including 170 PWNe and up to 100 halos. The extent
of diffusion suppression in halos has a limited impact on such prospects but
its magnitude has a strong influence. The level of diffuse emission from
unresolved populations in each survey is found to be dominated by halos and
comparable to large-scale interstellar radiation powered by cosmic rays above
0.1-1TeV. Pulsar halos are shown to be viable counterparts to a fraction of the
currently unidentified sources if they develop around most middle-aged pulsars
(abridged).Comment: 16 pages, 22 figures, accepted for publication in A&
Young star clusters as gamma ray emitters and their detection with Cherenkov Telescopes
Young massive star clusters as sites of strong stellar winds and supernova explosions may accelerate charged particles at high energies and produce gamma-rays. These sources may also contribute to the production of cosmic rays in our galaxy. At TeV energies several candidates have already been detected: Cygnus OB2, Westerlund 1 \& 2, W43, Pismis 22 and W49A. Our study addresses the issue of very young star clusters where no supernova has occurred yet. During the lifetime of a massive star (M), supersonic stellar winds do indeed release as much energy as a supernova explosion. As supernova remnants are already known as gamma-ray emitters our purpose is to avoid any ambiguity on the origin of a possible gamma ray emission and to fully assume a stellar wind contribution. In this work we first present a catalogue of potential gamma-ray emitting clusters and discuss the criteria used to built the catalogue. We hence model the expected energetic particle spectrum including escapes and losses. We deduce gamma-ray luminosities produced by Inverse Compton and pion decay emission of each cluster and their associated HII regions. We finally compare these gamma-ray luminosities with HESS-II and CTA Cherenkov telescopes sensitivities
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