Theoretical astrophysics and plasma physics at RPC

Turbulent Transport in Tokamak Plasmas with Rotational Shear

Physical Review Letters American Physical Society (APS) 106:17 (2011) 175004

Authors:

M Barnes, FI Parra, EG Highcock, AA Schekochihin, SC Cowley, CM Roach

Critically balanced ion temperature gradient turbulence in fusion plasmas

(2011)

Authors:

M Barnes, FI Parra, AA Schekochihin

Extracting science from surveys of our Galaxy

ArXiv 1104.2839 (2011)

Abstract:

Our knowledge of the Galaxy is being revolutionised by a series of photometric, spectroscopic and astrometric surveys. Already an enormous body of data is available from completed surveys, and data of ever increasing quality and richness will accrue at least until the end of this decade. To extract science from these surveys we need a class of models that can give probability density functions in the space of the observables of a survey -- we should not attempt to "invert" the data from the space of observables into the physical space of the Galaxy. Currently just one class of model has the required capability, so-called "torus models". A pilot application of torus models to understanding the structure of the Galaxy's thin and thick discs has already produced two significant results: a major revision of our best estimate of the Sun's velocity with respect to the Local Standard of Rest, and a successful prediction of the way in which the vertical velocity dispersion in the disc varies with distance from the Galactic plane.

Observable Signatures of EMRI Black Hole Binaries Embedded in Thin Accretion Disks

(2011)

Authors:

Bence Kocsis, Nicolas Yunes, Abraham Loeb

Galactic fountains and the rotation of disc-galaxy coronae

ArXiv 1103.5358 (2011)

Authors:

F Marinacci, F Fraternali, C Nipoti, J Binney, L Ciotti, P Londrillo

Abstract:

In galaxies like the Milky Way, cold (~ 10^4 K) gas ejected from the disc by stellar activity (the so-called galactic-fountain gas) is expected to interact with the virial-temperature (~ 10^6 K) gas of the corona. The associated transfer of momentum between cold and hot gas has important consequences for the dynamics of both gas phases. We quantify the effects of such an interaction using hydrodynamical simulations of cold clouds travelling through a hot medium at different relative velocities. Our main finding is that there is a velocity threshold between clouds and corona, of about 75 km/s, below which the hot gas ceases to absorb momentum from the cold clouds. It follows that in a disc galaxy like the Milky Way a static corona would be rapidly accelerated: the corona is expected to rotate and to lag, in the inner regions, by ~ 80-120 km/s with respect to the cold disc. We also show how the existence of this velocity threshold can explain the observed kinematics of the cold extra-planar gas.