Abstract
Observations of high redshift supernovae imply an accelerating Universe which can only be explained by an unusual energy component such as vacuum energy or quintessence. To assess the ability of current and future supernova data to constrain the properties of the dark energy, we allow its density to have arbitrary time-dependence, $\rho_X(z)$. This leads to an equation of state for the dark energy, $w_X(z)=p_X(z)/\rho_X(z)$, which is a free function of redshift $z$. We find that current type Ia supernova (SNe Ia) data are consistent with a cosmological constant, with large uncertainties at $z\ga 0.5$. We show that $\rho_X(z)/\rho_X(z=0)$ can be measured reasonably well to about $z=1.5$ using type Ia supernova data from realistic future SN Ia pencil beam surveys, provided that the weak energy condition (energy density of matter is nonnegative for any observer) is imposed. While it is only possible to differentiate between different models (say, quintessence and k-essence) at $z \la 1.5$ using realistic data, the correct trend in the time-dependence of the dark energy density can be clearly detected out to $z=2$, even in the presence of plausible systematic effects. This would allow us to determine whether the dark energy is a cosmological constant, or some exotic form of energy with a time-dependent density.
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