The Role for the Inner Disk in Mass Accretion to the Star in the Early Phase of Star Formation

Abstract

A physical mechanism that drives FU Orionis-type outbursts is reconsidered. We study the effect of inner part of a circumstellar disk covering a region from near the central star to the radius of approximately 5 AU (hereafter, the inner disk). Using the fluctuated mass accretion rate onto the inner disk M out, we consider the viscous evolution of the inner disk and the time variability of the mass accretion rate onto the central star M in by means of numerical calculation of an unsteady viscous accretion disk in a one-dimensional axisymmetric model. First, we calculate the evolution of the inner disk assuming an oscillating M out. It is shown that the time variability of M in does not coincide with M out due to viscous diffusion. Second, we investigate the properties of spontaneous outbursts with temporally constant M out. Outburst occur only in a limited range of mass accretion rates onto the inner disk 10-10<M out< 3× 10-6~ M yr-1 due to gravo-magneto limit cycle (GML). Finally, we discuss the case with a combination of episodic M out and accretion outbursts cause by the GML in the inner disk. The GML can drive accretion outbursts onto the star even for the case of fluctuating M out, although fluctuations of M decay during transmitting the inner disk inwards. We newly identified two modes of outburst which are spontaneous one and stimulated one. In a stimulated mode of outburst, M out does appear directly in M in (the latter defining the stellar accretion luminosity). In a spontaneous mode of outburst, M out appears as the interval between outbursts.