Theoretical astrophysics and plasma physics at RPC

Testing formation mechanisms of the Milky Way's thick disc with RAVE

ArXiv 1009.2052 (2010)

Authors:

Michelle Wilson, Amina Helmi, HL Morrison, MA Breddels, O Bienayme, J Binney, J Bland-Hawthorn, R Campbell, KC Freeman, JP Fulbright, BK Gibson, G Gilmore, EK Grebel, U Munari, JF Navarro, QA Parker, W Reid, G Seabroke, A Siebert, A Siviero, M Steinmetz, MEK Williams, RFG Wyse, T Zwitter

Abstract:

We study the eccentricity distribution of a thick disc sample of stars observed in the Radial Velocity Experiment (RAVE) and compare it to that expected in four simulations of thick disc formation in the literature (accretion of satellites, heating of a primordial thin disc during a merger, radial migration, and gas-rich mergers), as compiled by Sales et al. (2009). We find that the distribution of our sample is peaked at low eccentricities and falls off smoothly and rather steeply to high eccentricities. This distribution is fairly robust to changes in distances, thin disc contamination, and the particular thick disc sample used. Our results are inconsistent with what is expected for the pure accretion simulation, since we find that the dynamics of local thick disc stars implies that the majority must have formed "in situ". Of the remaining models explored, the eccentricity distribution of our stars appears to be most consistent with the gas-rich merger case.

A search for new members of the beta Pic, Tuc-Hor and epsilon Cha moving groups in the RAVE database

ArXiv 1009.1356 (2010)

Authors:

LL Kiss, A Moor, T Szalai, J Kovacs, D Bayliss, GF Gilmore, O Bienayme, J Binney, J Bland-Hawthorn, R Campbell, KC Freeman, JP Fulbright, BK Gibson, EK Grebel, A Helmi, U Munari, JF Navarro, QA Parker, W Reid, GM Seabroke, A Siebert, A Siviero, M Steinmetz, FG Watson, M Williams, RFG Wyse, T Zwitter

Abstract:

We report on the discovery of new members of nearby young moving groups, exploiting the full power of combining the RAVE survey with several stellar age diagnostic methods and follow-up high-resolution optical spectroscopy. The results include the identification of one new and five likely members of the beta Pictoris moving group, ranging from spectral types F9 to M4 with the majority being M dwarfs, one K7 likely member of the epsilon Cha group and two stars in the Tuc-Hor association. Based on the positive identifications we foreshadow a great potential of the RAVE database in progressing toward a full census of young moving groups in the solar neighbourhood.

Momentum injection in tokamak plasmas and transitions to reduced transport

(2010)

Authors:

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

Phase-space Lagrangian derivation of electrostatic gyrokinetics in general geometry

ArXiv 1009.0378 (2010)

Authors:

Felix I Parra, Ivan Calvo

Abstract:

Gyrokinetic theory is based on an asymptotic expansion in the small parameter $\epsilon$, defined as the ratio of the gyroradius and the characteristic length of variation of the magnetic field. In this article, this ordering is strictly implemented to compute the electrostatic gyrokinetic phase-space Lagrangian in general magnetic geometry to order $\epsilon^2$. In particular, a new expression for the complete second-order gyrokinetic Hamiltonian is provided, showing that in a rigorous treatment of gyrokinetic theory magnetic geometry and turbulence cannot be dealt with independently. The new phase-space gyrokinetic Lagrangian gives a Vlasov equation accurate to order $\epsilon^2$ and a Poisson equation accurate to order $\epsilon$. The final expressions are explicit and can be implemented into any simulation without further computations.

Galactic fountains and gas accretion

AIP Conference Proceedings 1240 (2010) 166-168

Authors:

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

Abstract:

Star-forming disc galaxies such as the Milky Way need to accrete ≳1 M⊙ of gas each year to sustain their star formation. This gas accretion is likely to come from the cooling of the hot corona, however it is still not clear how this process can take place. We present simulations supporting the idea that this cooling and the subsequent accretion are caused by the passage of cold galactic-fountain clouds through the hot corona. The Kelvin-Helmholtz instability strips gas from these clouds and the stripped gas causes coronal gas to condense in the cloud's wake. For likely parameters of the Galactic corona and of typical fountain clouds we obtain a global accretion rate of the order of that required to feed the star formation. © 2010 American Institute of Physics.