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Title: Relativistic Advection-Dominated Inflow-Outflow: Mass-loss rate variation of M87


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Radio-Loud AGN Model
These objects also have hot, ADAF-type accretion
flows, where the radiative cooling is very
inefficient and most of the dissipated energy is
advected into the black hole
Hot, tenuous disks are favorable sites for
relativistic particle acceleration because the
gas is collisionless
Up to the present date, the precise nature of the
mechanism responsible for transferring the
gravitational potential energy from the infalling
matter to the small population of nonthermal
particles that escape to form the jet is not yet
clear
  • (Credit C.M. Urry and P. Padovani )

3
Blandford-Znajek Mechanism
  • Rotation of black hole drags the inertial frame
  • This results in twisting of the magnetic field
    lines supported by the surrounding disk
  • The resulting magnetic stress is then released as
    a Poynting flux away from the hole
  • In this mechanism, the power of the jets is
    provided by the rotating hole

Is it possible to explain the outflows in terms
of well-understood microphysical processes
operating in the hot, tenuous disk, such as the
possible acceleration of the jet particles at a
standing accretion shock?
4
Connection with cosmic-ray acceleration
  • The discovery of the high-energy cosmic-ray
    spectrum prompted work on the acceleration of
    cosmic rays in SN shock waves via the first-order
    Fermi mechanism (Krymsky 1977 Bell 1978
    Blandford and Ostriker 1978)
  • These models were developed in the test-particle
    approximation (this must be abandoned if the
    compression ratio equals or exceeds 4)
  • We apply the same picture to understand particle
    acceleration in
  • accretion disks containing standing,
    centrifugally-supported shocks
  • In our disk/outflow model the liberated energy
    and entropy are thought to be lost from the disk
    in the vicinity of the shock via the escape of
    high-energy particles in ADAFs disks.

5
Particle acceleration in accretion disks
  • In this case there are two groups of particles
    the thermally-distributed background particles,
    and the higher-energy, relativistic test
    particles
  • Since we are employing the test particle
    approximation, the pressure of the accelerated
    particles is not included in the dynamics
  • In ADAF disks, the mean free path ?ii for ion-ion
    collisions is much longer than the disk height
    the gas is collisionless
  • The mean free path ?mag for collisions with
    magnetic waves is much shorter than ?ii for the
    thermal particles, and much longer than ?ii for
    the relativistic particles we assume collective
    processes thermalize the background
  • Therefore the background particles cross the
    shock ONCE, and the relativistic test particles
    cross the shock MULTIPLE times
  • The maximum particle energy that can be produced
    in this model depends on the magnetic wave
    distribution via the recoil effect

6
Isothermal shocks (TT_)
  • In isothermal shocks radiative cooling is very
    efficient
  • More energy is lost than in the isentropic or RH
    shocks
  • The entropy decreases as the gas crosses the
    shock
  • This implies that the sound speed and the
    thickness of the flow remain unchanged through
    the shock
  • This type of shock TT_, but elt e_ and KltK_
  • The compression ratio is maximized for a given
    Mach number, enhancing particle acceleration
  • We focus on isothermal shocks here and therefore
    we assume that particles escape from the disk
    only at the shock location
  • We will show the gas is strongly bound in the
    post-shock region

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  • Equations describing structure of adiabatic,
    inviscid accretion flows with isothermal shocks
  • Sonic Point Analysis
  • Shock Point Analysis

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  • Transport equation that governs the relativistic
    particle energy/space distribution
  • Assumption about Spatial Diffusion Coefficient
  • Assumption about Vertical Escape
  • Solutions for the Relativistic Number Energy
    Densities

9
Disk-Jet Connection
10
Flow structure with/without shock
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Results M87 Sgr A
  • Our model then gives for the escape energy at the
    shock radius r r , which is the jet radius
    rjet 22 rg and rjet 16 rg for M87 and Sgr A,
    respectively.
  • Our results indicate that the shock acceleration
    mechanism can produce relativistic outflows with
    terminal Lorentz factor of 8 (M87) and 7 (Sgr
    A), and the total powers comparable to those
    estimated in M87 and Sgr A.
  • From observations, Biretta et al. (2002) suggest
    that the M87 jet forms in a region no larger than
    rjet lt 30 rg Biretta et al. (1999) estimate
    for the bulk flow in the jet of M87.
  • In the case of Sgr A, our disk-jet model
    indicates that the jet forms at rjet 16 rg
    which is fairly close to the value suggested by
    Yuan (2000) model. However, future observational
    work will be needed to test our prediction for
    the asymptotic Lorentz factor of Sgr A, since no
    reliable observational estimate for that quantity
    is currently available.

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