1 / 18

Incompressible df/dt=0

Incompressible df/dt=0 N star identical particles moving in a small bundle in phase space (Vol= Δ x Δ p ), phase space deforms but maintains its area. Likewise for y-p y and z-p z . Phase space density f=Nstars/ Δ x Δ p ~ const. p x. p x. x. x. Stars flow in phase-space.

hestia
Download Presentation

Incompressible df/dt=0

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Incompressible df/dt=0 • Nstar identical particles moving in a small bundle in phase space (Vol=Δx Δ p), • phase space deforms but maintains its area. • Likewise for y-py and z-pz. Phase space density f=Nstars/Δx Δ p ~ const px px x x

  2. Stars flow in phase-space • Flow of points in phase space ~ stars moving along their orbits. • phase space coords:

  3. Collisionless Boltzmann Equation • Collisionless df/dt=0: • Vector form

  4. DF & its 0th ,1st , 2nd moments

  5. E.g: rms speed of air particles in a box dx3 :

  6. CBE  Moment/Jeans Equations • Phase space incompressible df(w,t)/dt=0, where w=[x,v]: CBE • taking moments U=1, vj, vjvk by integrating over all possible velocities

  7. 0th moment (continuity) eq. • define spatial density of stars n(x) • and the mean stellar velocity v(x) • then the zeroth moment equation becomes

  8. 2nd moment Equation similar to the Euler equation for a fluid flow: • last term of RHS represents pressure force

  9. Meaning of pressure in star system • What prevents a non-rotating star cluster collapse into a BH? • No systematic motion as in Milky Way disk. • But random orbital angular momentum of stars!

  10. Anisotropic Stress Tensor • describes a pressure which is • perhaps stronger in some directions than other • the tensor is symmetric, can be diagonalized • velocity ellipsoid with semi-major axes given by

  11. Prove Tensor Virial Theorem (p212 of BT) • Many forms of Viral theorem, E.g.

  12. Jeans theorem • For most stellar systems the DF depends on (x,v) through generally integrals of motion (conserved quantities), • Ii(x,v), i=1..3  f(x,v) = f(I1(x,v), I2(x,v), I3(x,v)) • E.g., in Spherical Equilibrium, f is a function of energy E(x,v) and ang. mom. vector L(x,v).’s amplitude and z-component

  13. An anisotropic incompressible spherical fluide.g, f(E,L) =exp(-E/σ02)Lβ • Verify <Vr2> = σ02, <Vt2>=2(1-β) σ02 • Verify <Vr> = 0 • Verify CBE is satisfied along the orbit or flow: 0 for static potential, 0 for spherical potential So f(E,L) constant along orbit or flow

  14. Apply JE & PE to measure Dark Matter • A bright sub-component of observed density n*(r) and anisotropic velocity dispersions <Vt2>= 2(1-β)<Vr2> • in spherical potential φ(r) from total (+dark) matter density ρ(r)

  15. e.g., Measure total Matter density r(r) Assume anistropic parameter beta, substitute JE for stars of density n* into PE, get • all quantities on the LHS are, in principle, determinable from observations.

  16. Spherical Isotropic f(E) Equilibrium Systems • ISOTROPIC β=0:The distribution function f(E) only depends on |V| the modulus of the velocity, same in all velocity directions. Note:the tangential direction has  and  components

  17. Non-SELF-GRAVITATING: There are additional gravitating matter • The matter density that creates the potential is NOT equal to the density of stars. • e.g., stars orbiting a black hole is non-self-gravitating.

  18. Additive: subcomponents add upto the total gravitational mass

More Related