Professor James Binney FRS

Dynamical friction in modified Newtonian dynamics

ArXiv 0802.1122 (2008)

Authors:

C Nipoti, L Ciotti, J Binney, P Londrillo

Abstract:

We have tested a previous analytical estimate of the dynamical friction timescale in Modified Newtonian Dynamics (MOND) with fully non-linear N-body simulations. The simulations confirm that the dynamical friction timescale is significantly shorter in MOND than in equivalent Newtonian systems, i.e. systems with the same phase-space distribution of baryons and additional dark matter. An apparent conflict between this result and the long timescales determined for bars to slow and mergers to be completed in previous N-body simulations of MOND systems is explained. The confirmation of the short dynamical-friction timescale in MOND underlines the challenge that the Fornax dwarf spheroidal poses to the viability of MOND.

Accretion of gas onto nearby spiral galaxies

ArXiv 0802.0496 (2008)

Authors:

Filippo Fraternali, James Binney

Abstract:

We present evidence for cosmological gas accretion onto spiral galaxies in the local universe. The accretion is seen through its effects on the dynamics of the extra-planar neutral gas. The accretion rates that we estimate for two nearby spiral galaxies are of the order of their star formation rates. Our model shows that most of the extra-planar gas is produced by supernova feedback (galactic fountain) and only 10-20 % comes from accretion. The accreting material must have low specific angular momentum about the disc's spin axis, although the magnitude of the specific angular-momentum vector can be higher. We also explore the effects of a hot corona on the dynamics of the extra-planar gas and find that it is unlikely to be responsible for the observed kinematical pattern and the source of accreted gas. However, the interaction with the fountain flow should profoundly affect the hydrodynamics of the corona.

Galactic kinematics with RAVE data: I. The distribution of stars towards the Galactic poles

ArXiv 0801.2120 (2008)

Authors:

L Veltz, O Bienaymé, KC Freeman, J Binney, J Bland-Hawthorn, BK Gibson, G Gilmore, EK Grebel, A Helmi, U Munari, JF Navarro, QA Parker, GM Seabroke, A Siebert, M Steinmetz, FG Watson, M Williams, RFG Wyse, T Zwitter

Abstract:

We analyze the distribution of G and K type stars towards the Galactic poles using RAVE and ELODIE radial velocities, 2MASS photometric star counts, and UCAC2 proper motions. The combination of photometric and 3D kinematic data allows us to disentangle and describe the vertical distribution of dwarfs, sub-giants and giants and their kinematics. We identify discontinuities within the kinematics and magnitude counts that separate the thin disk, thick disk and a hotter component. The respective scale heights of the thin disk and thick disk are 225$\pm$10 pc and 1048$\pm$36 pc. We also constrain the luminosity function and the kinematic distribution function. The existence of a kinematic gap between the thin and thick disks is incompatible with the thick disk having formed from the thin disk by a continuous process, such as scattering of stars by spiral arms or molecular clouds. Other mechanisms of formation of the thick disk such as `created on the spot' or smoothly `accreted' remain compatible with our findings.

Galactic dynamics

Princeton Univ Pr, 2008

Authors:

James Binney, Scott Tremaine

COMMISSION 28: GALAXIES

Proceedings of the International Astronomical Union Cambridge University Press (CUP) 3:T26B (2007) 183-183

Authors:

Elaine M Sadler, Françoise Combes, Sadanori Okamura, James J Binney, Anthony P Fairall, Timothy M Heckman, Simon J Lilly, Valentina Karachentseva, Renée C Kraan-Korteweg, Gillian R Knapp, Bruno Leibundgut, Jayant V Narlikar