Evolution of Tidal Disruption Event Disks with Magnetically Driven Winds

We present a time-dependent, one-dimensional magnetically driven disk-wind model based on magnetohydrodynamical (MHD) equations in the context of tidal disruption events (TDEs). We assume that the disk is geometrically thin and gas-pressure dominant and explicitly take into account magnetic braking as well as turbulent viscosity by an extended alpha viscosity prescription. We find a particular wind solution for a set of basic equations that satisfies the necessary and sufficient conditions for vertically unbound MHD flows. The solution demonstrates that the disk evolves with losing mass due to wind and accretion from the initial Gaussian density distribution. We confirm that the mass accretion rate follows the power law of time t^-19/16 at late times if the wind is absent, which corresponds to the classical solution of Cannizzo et al. (1990). We find that the mass accretion rate is steeper than the t^-19/16 curve if the disk wind is present. This is because the wind removes a significant fraction of the mass and angular momentum. Mass accretion is further induced by magnetic braking, known as a wind-driven accretion mechanism, resulting in more rapid decay with time in both the mass accretion and loss rates. The ultraviolet (UV) luminosity is the highest among the optical, UV, and X-ray luminosities from early to late evolutionary phases, suggesting optical and X-ray emissions from the disk are observationally insignificant due to magnetically driven winds in TDEs. Our model predicts that late-time bolometric light curves steeper than t^-19/16 in UV-bright TDEs potentially serve as compelling indicators for magnetically driven winds.