Your search keyword '"Xufen Wu"' showing total 2 results

1. N-body simulations for testing the stability of triaxial galaxies in MOND.

Author

Xufen Wu, HongSheng Zhao, Yougang Wang, Llinares, Claudio, and Knebe, Alexander

Subjects

*SIMULATION methods & models, *GALAXIES, *ELLIPTICAL galaxies, *GRAVITY, *NEWTONIAN cosmology

Abstract

We perform a stability test of triaxial models in Modified Newtonian Dynamics (MOND) using N-body simulations. The triaxial models considered here have densities that vary with in the centre and at large radii. The total mass of the model varies from 108 to , representing the mass scale of dwarfs to medium-mass elliptical galaxies, respectively, from deep MOND to quasi-Newtonian gravity. We build triaxial galaxy models using the Schwarzschild technique, and evolve the systems for 200 Keplerian dynamical times (at the typical length-scale of 1.0 kpc). We find that the systems are virial overheating, and in quasi-equilibrium with the relaxation taking approximately 5 Keplerian dynamical times (1.0 kpc). For all systems, the change of the inertial (kinetic) energy is less than 10 per cent (20 per cent) after relaxation. However, the central profile of the model is flattened during the relaxation and the (overall) axis ratios change by roughly 10 per cent within 200 Keplerian dynamical times (at 1.0 kpc) in our simulations. We further find that the systems are stable once they reach the equilibrium state. [ABSTRACT FROM AUTHOR]

Published

2009

2. Milky Way potentials in cold dark matter and MOdified Newtonian Dynamics. Is the Large Magellanic Cloud on a bound orbit?

Author

Xufen Wu, Famaey, Benoit, Gentile, Gianfranco, Perets, Hagai, and Hong Sheng Zhao

Subjects

*MILKY Way, *DARK matter, *MAGELLANIC clouds, *ORBITS (Astronomy), *GALAXIES, *ASTRONOMY

Abstract

We compute the Milky Way potential in different cold dark matter (CDM) based models, and compare these with the MOdified Newtonian Dynamics (MOND) framework. We calculate the axial ratio of the potential in various models, and find that isopotentials are less spherical in MOND than in CDM potentials. As an application of these models, we predict the escape velocity as a function of the position in the Galaxy. This could be useful in comparing with future data from planned or already-underway kinematic surveys (RAVE, SDSS, SEGUE, SIM, Gaia or the hypervelocity stars survey). In addition, the predicted escape velocity is compared with the recently measured high proper motion velocity of the Large Magellanic Cloud (LMC). To bind the LMC to the Galaxy in a MOND model, while still being compatible with the RAVE-measured local escape speed at the Sun's position, we show that an external field modulus of less than is needed. [ABSTRACT FROM AUTHOR]

Published

2008