the formation of stars and planets day 2, topic 2: self-gravitating hydrostatic gas spheres lecture...
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The formation of stars and planets
Day 2, Topic 2:
Self-gravitatinghydrostaticgas spheres
Lecture by: C.P. Dullemond
B68: a self-gravitating stable cloud
Bok Globule
Relatively isolated, hence not many external disturbances
Though not main mode of star formation, their isolation makes them good test-laboratories for theories!
Hydrostatic self-gravitating spheres
• Spherical symmetry
• Isothermal
• Molecular
Equation of hydrost equilibrium:
Equation for grav potential:
Equation of state:
From here on the material is partially based on the book by Stahler & Palla “Formation of Stars”
Hydrostatic self-gravitating spheres
Spherical coordinates:
Equation of state:
Equation of hydrostat equilibrium:
Equation for grav potential:
Hydrostatic self-gravitating spheres
Spherical coordinates:
Hydrostatic self-gravitating spheres
Numerical solutions:
Hydrostatic self-gravitating spheres
Numerical solutions:
Exercise: write a small program to integrate these equations, for a given central density
Hydrostatic self-gravitating spheres
Numerical solutions:
Hydrostatic self-gravitating spheres
Numerical solutions:Plotted logarithmically(which we will usually do from now on)
Bonnor-Ebert Sphere
Hydrostatic self-gravitating spheres
Numerical solutions:Different starting o :a family of solutions
Hydrostatic self-gravitating spheres
Numerical solutions: Singular isothermal sphere(limiting solution)
Hydrostatic self-gravitating spheres
Numerical solutions:Boundary condition:Pressure at outer edge = pressure of GMC
Hydrostatic self-gravitating spheres
Numerical solutions:Another boundary condition:Mass of clump is given
One boundary condition too many!Must replace c inner BC with one of outer BCs
Hydrostatic self-gravitating spheres
• Summary of BC problem:– For inside-out integration the paramters are c and ro.
– However, the physical parameters are M and Po
• We need to reformulate the equations:– Write everything dimensionless– Consider the scaling symmetry of the solutions
Hydrostatic self-gravitating spheres
All solutions are scaled versions of each other!
Hydrostatic self-gravitating spheres
A dimensionless, scale-free formulation:
Hydrostatic self-gravitating spheres
A dimensionless, scale-free formulation:
New coordinate:
New dependent variable:
Lane-Emden equation
Hydrostatic self-gravitating spheres
A dimensionless, scale-free formulation:
Boundary conditions (both at =0):
Numerically integrate inside-out
Hydrostatic self-gravitating spheres
A dimensionless, scale-free formulation:
A direct relation between o/c and o
Remember:
Hydrostatic self-gravitating spheres
• We wish to find a recipe to find, for given M and Po, the following: c (central density of sphere)
– ro (outer radius of sphere)
– Hence: the full solution of the Bonnor-Ebert sphere
• Plan:– Express M in a dimensionless mass ‘m’
– Solve for c/o (for given m)
(since o follows from Po = ocs2 this gives us c)
– Solve for o (for given c/o)
(this gives us ro)
Hydrostatic self-gravitating spheres
Mass of the sphere:
Use Lane-Emden Equation to write:
This gives for the mass:
Hydrostatic self-gravitating spheres
Dimensionless mass:
Hydrostatic self-gravitating spheres
Dimensionless mass:
Recipe: Convert M in m (for given Po), find c/o from figure,
obtain c, use dimless solutions to find ro, make BE sphere
Stability of BE spheres
• Many modes of instability
• One is if dPo/dro > 0– Run-away collapse, or– Run-away growth, followed by collapse
• Dimensionless equivalent: dm/d(c/o) < 0
unstable
unstable
Stability of BE spheres
Maximum density ratio =1 / 14.1
Bonnor-Ebert mass
Ways to cause BE sphere to collapse:
• Increase external pressure until MBE<M
• Load matter onto BE sphere until M>MBE
m1 = 1.18
Bonnor-Ebert massNow plotting the x-axis linear (only up to c/o =14.1) and divide y-axis through BE mass:
Hydrostatic clouds with large c/o must be very rare...
BE ‘Sphere’: Observations of B68
Alves, Lada, Lada 2001
Magnetic field support / ambipolar diff.
As mentioned in previous chapter, magnetic fields can partly support cloud and prevent collapse. Slow ambipolar diffusion moves fields out of cloud, which could trigger collapse.
Models by Lizano & Shu (1989) show this elegantly:
• Magnetic support only in x-y plane, so cloud is flattened.
• Dashed vertical line is field in beginning, solid: after some time. Field moves inward geometrically, but outward w.r.t. the matter.