We study the dynamics of a quintessence model based on two interacting scalar fields. The model can account for the (recent) accelerated expansion of the Universe suggested by astronomical observations. Acceleration can be permanent or temporary and, for both scenarios, it is possible to obtain suitable values for the cosmological parameters while satisfying the nucleosynthesis constraint on the quintessence energy density. We argue that the model dynamics can be made consistent with a stable zero-energy relaxing supersymmetric vacuum.Recent observations of type Ia supernovae, together with Cosmic Microwave Background (CMB) and cluster mass distribution data [1][2][3] indicate that the Universe is flat, in agreement with the inflationary prediction, accelerating and that the energy density of (baryonic plus dark) matter is smaller than the critical density. Thus, observations suggest that the dynamics of the Universe at present is dominated by a negative pressure component, the main candidates being a cosmological constant and a slowly-varying vacuum energy, usually referred to as dark energy or quintessence [4,5] (an evolving vacuum energy was discussed somewhat earlier, e.g. [6]). The main difference between the cosmological constant and quintessence scenarios is that, for quintessence, the equation of state parameter, w Q ≡ p/ρ, varies with time and approaches a present value w Q < −0.6, whilst for the cosmological constant, it remains fixed at w Λ = −1.Several quintessence models have been put foward, most of them based on a scalar field which was subdominant in the early Universe and, more recently, has started to dominate the energy density of non-relativistic matter. Theoretical suggestions include a scalar field endowed with exponential [7][8][9][10] or inverse power law potentials [11], the string theory dilaton in the context of gaugino condensation [12], an axion field with an almost massless quark [13], scalar-tensor theories of gravity [14], or one of the fields arising from the compactification process in the multidimensional Einstein-Yang-Mills system [15]. Some of these models address the "cosmic coincidence" problem i.e. the question of explaining why the vacuum energy or scalar field dominates the Universe only recently. In tracker models, the tracker field rolls down a potential according to an attractor-like solution to the equations of motion, causing the energy density of the quintessence field to track the equation of state of the background energy component independently of initial conditions [11]. However, in these models, the overall scale of the potential has to be fine-tuned in order for the quintessence energy to overtake the matter density at present.In k-essence models [16], as a result of the dynamics, tracking of the background energy density can only occur in the radiation epoch; at the onset of matterdomination, the k-essence field energy density drops sharply, increasing again and overtaking the matter energy density at roughly the current epoch. At least in the original propo...
