Rotational Brownian motion (astronomy)

Last updated November 10, 2019

In astronomy, rotational Brownian motion is the random walk in orientation of a binary star's orbital plane, induced by gravitational perturbations from passing stars.

A random walk is a mathematical object, known as a stochastic or random process, that describes a path that consists of a succession of random steps on some mathematical space such as the integers. An elementary example of a random walk is the random walk on the integer number line, $, which starts at 0 and at each step moves +1 or -1 with equal probability. Other examples include the path traced by a molecule as it travels in a liquid or a gas, the search path of a foraging animal, the price of a fluctuating stock and the financial status of a gambler: all can be approximated by random walk models, even though they may not be truly random in reality. As illustrated by those examples, random walks have applications to engineering and many scientific fields including ecology, psychology, computer science, physics, chemistry, biology as well as economics. Random walks explain the observed behaviors of many processes in these fields, and thus serve as a fundamental model for the recorded stochastic activity. As a more mathematical application, the value of π can be approximated by the use of random walk in an agent-based modeling environment. The term random walk was first introduced by Karl Pearson in 1905.$

A binary star is a star system consisting of two stars orbiting around their common barycenter. Systems of two or more stars are called multiple star systems. These systems, especially when more distant, often appear to the unaided eye as a single point of light, and are then revealed as multiple by other means.

Theory

Consider a binary that consists of two massive objects (stars, black holes etc.) and that is embedded in a stellar system containing a large number of stars. Let $M_{1}$ and $M_{2}$ be the masses of the two components of the binary whose total mass is $M_{12}=M_{1}+M_{2}$ . A field star that approaches the binary with impact parameter $p$ and velocity $V$ passes a distance $r_{p}$ from the binary, where

The impact parameter $is defined as the perpendicular distance between the path of a projectile and the center of a potential field created by an object that the projectile is approaching. It is often referred to in nuclear physics and in classical mechanics.$

$p^{2}=r_{p}^{2}\left(1+2GM_{12}/V^{2}r_{p}\right)\approx 2GM_{12}r_{p}/V^{2};$

the latter expression is valid in the limit that gravitational focusing dominates the encounter rate. The rate of encounters with stars that interact strongly with the binary, i.e. that satisfy $r_{p}<a$ , is approximately $n\pi p^{2}\sigma =2\pi GM_{12}na/\sigma$ where $n$ and $\sigma$ are the number density and velocity dispersion of the field stars and $a$ is the semi-major axis of the binary.

As it passes near the binary, the field star experiences a change in velocity of order

$\Delta V\approx V_{\rm {bin}}={\sqrt {GM_{12}/a}}$ ,

where $V_{\rm {bin}}$ is the relative velocity of the two stars in the binary. The change in the field star's specific angular momentum with respect to the binary, $l$ , is then Δl ≈ aV_bin. Conservation of angular momentum implies that the binary's angular momentum changes by Δl_bin ≈ -(m/μ₁₂)Δl where m is the mass of a field star and μ₁₂ is the binary reduced mass. Changes in the magnitude of l_bin correspond to changes in the binary's orbital eccentricity via the relation e = 1 - l_b²/GM₁₂μ₁₂a. Changes in the direction of l_bin correspond to changes in the orientation of the binary, leading to rotational diffusion. The rotational diffusion coefficient is

In physics, the reduced mass is the "effective" inertial mass appearing in the two-body problem of Newtonian mechanics. It is a quantity which allows the two-body problem to be solved as if it were a one-body problem. Note, however, that the mass determining the gravitational force is not reduced. In the computation one mass can be replaced with the reduced mass, if this is compensated by replacing the other mass with the sum of both masses. The reduced mass is frequently denoted by $(mu), although the standard gravitational parameter is also denoted by . It has the dimensions of mass, and SI unit kg.$

$\langle \Delta \xi ^{2}\rangle =\langle \Delta l_{\rm {bin}}^{2}\rangle /l_{\rm {bin}}^{2}\approx \left({m \over M_{12}}\right)^{2}\langle \Delta l^{2}\rangle /GM_{12}a\approx {m \over M_{12}}{G\rho a \over \sigma }$

where ρ = mn is the mass density of field stars.

Let F(θ,t) be the probability that the rotation axis of the binary is oriented at angle θ at time t. The evolution equation for F is ^[1]

${\partial F \over \partial t}={1 \over \sin \theta }{\partial \over \partial \theta }\left(\sin \theta {\langle \Delta \xi ^{2}\rangle \over 4}{\partial F \over \partial \theta }\right).$

If <Δξ²>, a, ρ and σ are constant in time, this becomes

${\partial F \over \partial \tau }={1 \over 2}{\partial \over \partial \mu }\left[(1-\mu ^{2}){\partial F \over \partial \mu }\right]$

where μ = cos θ and τ is the time in units of the relaxation time t_rel, where

$t_{\rm {rel}}\approx {M_{12} \over m}{\sigma \over G\rho a}.$

The solution to this equation states that the expectation value of μ decays with time as

${\overline {\mu }}={\overline {\mu }}_{0}e^{-\tau }.$

Hence, t_rel is the time constant for the binary's orientation to be randomized by torques from field stars.

Applications

Rotational Brownian motion was first discussed in the context of binary supermassive black holes at the centers of galaxies.^[2] Perturbations from passing stars can alter the orbital plane of such a binary, which in turn alters the direction of the spin axis of the single black hole that forms when the two coalesce.

A supermassive black hole is the largest type of black hole, containing a mass of the order of hundreds of thousands to billions of times the mass of the Sun (M_☉). Black holes are a class of astronomical object that have undergone gravitational collapse, leaving behind spheroidal regions of space from which nothing can escape, not even light. Observational evidence indicates that nearly all large galaxies contain a supermassive black hole, located at the galaxy's center. In the case of the Milky Way, the supermassive black hole corresponds to the location of Sagittarius A* at the Galactic Core. Accretion of interstellar gas onto supermassive black holes is the process responsible for powering quasars and other types of active galactic nuclei.

Rotational Brownian motion is often observed in N-body simulations of galaxies containing binary black holes.^[3]^[4] The massive binary sinks to the center of the galaxy via dynamical friction where it interacts with passing stars. The same gravitational perturbations that induce a random walk in the orientation of the binary, also cause the binary to shrink, via the gravitational slingshot. It can be shown^[2] that the rms change in the binary's orientation, from the time the binary forms until the two black holes collide, is roughly

$\delta \theta \approx {\sqrt {20m/M_{12}}}.$

In a real galaxy, the two black holes would eventually coalesce due to emission of gravitational waves. The spin axis of the coalesced hole will be aligned with the angular momentum axis of the orbit of the pre-existing binary. Hence, a mechanism like rotational Brownian motion that affects the orbits of binary black holes can also affect the distribution of black hole spins. This may explain in part why the spin axes of supermassive black holes appear to be randomly aligned with respect to their host galaxies.^[5]

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References

↑ Debye, P. (1929). Polar Molecules . Dover.
1 2 Merritt, D. (2002), Rotational Brownian Motion of a Massive Binary, The Astrophysical Journal, 568, 998-1003.
↑ Löckmann, U. and Baumgardt, H. (2008), Tracing intermediate-mass black holes in the Galactic Centre, Monthly Notices of the Royal Astronomical Society , 384, 323-330.
↑ Matsubayashi, T., Makino, J. and Ebisuzaki, T. (2007), Evolution of an IMBH in the Galactic Nucleus with a Massive Central Black Hole, The Astrophysical Journal, 656, 879-896
↑ Kinney, A. et al. (2000), Jet Directions in Seyfert Galaxies, The Astrophysical Journal, 537, 152-177

External links

Gravitational Scattering Review article on the dynamics of encounters between binaries and single stars.

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[1] Debye, P. (1929). Polar Molecules . Dover.

[DM-2] 1 2 Merritt, D. (2002), Rotational Brownian Motion of a Massive Binary, The Astrophysical Journal, 568, 998-1003.

[3] Löckmann, U. and Baumgardt, H. (2008), Tracing intermediate-mass black holes in the Galactic Centre, Monthly Notices of the Royal Astronomical Society , 384, 323-330.

[4] Matsubayashi, T., Makino, J. and Ebisuzaki, T. (2007), Evolution of an IMBH in the Galactic Nucleus with a Massive Central Black Hole, The Astrophysical Journal, 656, 879-896

[5] Kinney, A. et al. (2000), Jet Directions in Seyfert Galaxies, The Astrophysical Journal, 537, 152-177