Numerical Simulations of Winds Driven by Radiation Force from the Corona above a Thin Disk

Abstract

Abstract Observations show that winds can be driven from the innermost region (inside a 50 Schwarschild radius) of a thin disk. It is interesting to study the winds launched from the innermost region. A hot corona above the black hole (BH) thin disk is irradiated by the disk. We perform two-dimensional hydrodynamical simulations to study the winds driven by radiation force from the corona in the innermost regions. The hard X-ray spectrum from active galactic nuclei (AGNs) suggests that the corona temperature is about 109 K, so that we mainly analyze the properties of winds (or outflows) from the 109 K corona. The disk luminosity plays an important role in driving the outflows. The more luminous the disk, the stronger the outflows. Mass outflow rate ( ) at a 90 Schwarschild radius depends on disk luminosity, which can be described as (Γ is the ratio of the disk luminosity to the Eddington luminosity). In the case of high luminosity (e.g., Γ = 0.75), the supersonic outflows with maximum speed 1.0 × 104 Km s−1 are launched at ∼17°–30° and ∼50°–80° away from the pole axis. The Bernoulli parameter keeps increasing with the outward propagation of outflows. The radiation force keeps accelerating the outflows when outflows move outward. Therefore, we can expect the outflows to escape from the BH gravity and go to the galactic scale. The interaction between outflows and interstellar medium may be an important AGN feedback process.