In the 1940s,
Carl Friedrich von Weizsäcker developed model for the formation of stars from accreting gas.
α-Disk model Shakura and
Sunyaev (1973) By using the equation of
hydrostatic equilibrium, combined with conservation of
angular momentum and assuming that the disk is thin, the equations of disk structure may be solved in terms of the \alpha parameter. Many of the observables depend only weakly on \alpha, so this theory is predictive even though it has a free parameter. Using
Kramers' opacity law it is found that :H = 1.7\times 10^8\alpha^{-1/10}\dot{M}^{3/20}_{16} m_1^{-3/8} R^{9/8}_{10}f^{3/5} {\rm cm} :T_c = 1.4\times 10^4 \alpha^{-1/5}\dot{M}^{3/10}_{16} m_1^{1/4} R^{-3/4}_{10}f^{6/5}{\rm K} :\rho = 3.1\times 10^{-8}\alpha^{-7/10}\dot{M}^{11/20}_{16} m_1^{5/8} R^{-15/8}_{10}f^{11/5}{\rm g\ cm}^{-3} where T_c and \rho are the mid-plane temperature and density respectively. \dot{M}_{16} is the accretion rate, in units of 10^{16}{\rm g\ s}^{-1}, m_1 is the mass of the central accreting object in units of a solar mass, M_\bigodot, R_{10} is the radius of a point in the disk, in units of 10^{10}{\rm cm}, and f = \left[1-\left(\frac{R_\star}{R}\right)^{1/2} \right]^{1/4}, where R_\star is the radius where angular momentum stops being transported inward. The Shakura–Sunyaev α-disk model is both thermally and viscously unstable. An alternative model, known as the \beta-disk, which is stable in both senses assumes that the viscosity is proportional to the gas pressure \nu \propto \alpha p_{\mathrm{gas}}. In the standard Shakura–Sunyaev model, viscosity is assumed to be proportional to the total pressure p_{\mathrm{tot}} = p_{\mathrm{rad}} + p_{\mathrm{gas}} = \rho c_{\rm s}^2 since \nu = \alpha c_{\rm s} H = \alpha c_s^2/\Omega = \alpha p_{\mathrm{tot}}/(\rho \Omega). The Shakura–Sunyaev model assumes that the disk is in local thermal equilibrium, and can radiate its heat efficiently. In this case, the disk radiates away the viscous heat, cools, and becomes geometrically thin. However, this assumption may break down. In the radiatively inefficient case, the disk may "puff up" into a
torus or some other three-dimensional solution like an Advection Dominated Accretion Flow (ADAF). The ADAF solutions usually require that the accretion rate is smaller than a few percent of the
Eddington limit. Another extreme is the case of
Saturn's rings, where the disk is so gas-poor that its angular momentum transport is dominated by solid body collisions and disk-moon gravitational interactions. The model is in agreement with recent astrophysical measurements using
gravitational lensing.
Magnetorotational instability , a
Herbig–Haro object surrounded by an accretion disk Balbus and Hawley (1991) It can be shown that in the presence of such a spring-like tension the Rayleigh stability criterion is replaced by :\frac{d\Omega^2}{d \ln R}>0. Most astrophysical disks do not meet this criterion and are therefore prone to this magnetorotational instability. The magnetic fields present in astrophysical objects (required for the instability to occur) are believed to be generated via
dynamo action.
Magnetic fields and jets Accretion disks are usually assumed to be threaded by the external magnetic fields present in the
interstellar medium. These fields are typically weak (about few micro-Gauss), but they can get anchored to the matter in the disk, because of its high
electrical conductivity, and carried inward toward the central
star. This process can concentrate the
magnetic flux around the centre of the disk giving rise to very strong magnetic fields. Formation of powerful
astrophysical jets along the rotation axis of accretion disks requires a large scale
poloidal magnetic field in the inner regions of the disk. Such magnetic fields may be advected inward from the interstellar medium or generated by a magnetic dynamo within the disk. Magnetic fields strengths at least of order 100 Gauss seem necessary for the magneto-centrifugal mechanism to launch powerful jets. There are problems, however, in carrying external magnetic flux inward toward the central star of the disk. High electric conductivity dictates that the magnetic field is frozen into the matter which is being accreted onto the central object with a slow velocity. However, the plasma is not a perfect electric conductor, so there is always some degree of dissipation. The magnetic field diffuses away faster than the rate at which it is being carried inward by accretion of matter. A simple solution is assuming a
viscosity much larger than the
magnetic diffusivity in the disk. However, numerical simulations and theoretical models show that the viscosity and magnetic diffusivity have almost the same order of magnitude in magneto-rotationally turbulent disks. Some other factors may possibly affect the advection/diffusion rate: reduced turbulent magnetic diffusion on the surface layers; reduction of the
Shakura–
Sunyaev viscosity by magnetic fields; and the generation of large scale fields by small scale MHD turbulence –a large scale dynamo. In fact, a combination of different mechanisms might be responsible for efficiently carrying the external field inward toward the central parts of the disk where the jet is launched. Magnetic buoyancy, turbulent pumping and turbulent diamagnetism exemplify such physical phenomena invoked to explain such efficient concentration of external fields. ==Analytic models==