p-brane dynamics in N+1-dimensional FRW universes

Abstract

We study the evolution of maximally symmetric p-branes with a Sp-i Ri topology in flat expanding or collapsing homogeneous and isotropic universes with N+1 dimensions (with N 3, p < N, 0 i < p). We find the corresponding equations of motion and compute new analytical solutions for the trajectories in phase space. For a constant Hubble parameter, H, and i=0 we show that all initially static solutions with a physical radius below a certain critical value, rc0, are periodic while those with a larger initial radius become frozen in comoving coordinates at late times. We find a stationary solution with constant velocity and physical radius, rc, and compute the root mean square velocity of the periodic p-brane solutions and the corresponding (average) equation of state of the p-brane gas. We also investigate the p-brane dynamics for H ≠ constant in models where the evolution of the universe is driven by a perfect fluid with constant equation of state parameter, w= Pp/p, and show that a critical radius, rc, can still be defined for -1 w < wc with wc=(2-N)/N. We further show that for w wc the critical radius is given approximately by rc H (wc-w)γc with γc=-1/2 (rc H ∞ when w wc). Finally, we discuss the impact that the large scale dynamics of the universe can have on the macroscopic evolution of very small loops.