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Novae and Mixing

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Title: Novae and Mixing


1
Novae and Mixing
  • John ZuHone
  • ASCI/Alliances Center for Thermonuclear Flashes
  • University of Chicago

2
Overview
  • Purpose
  • What is FLASH?
  • Mixing in Novae
  • Setting Up the Problem
  • Doing the Problem
  • Conclusions

3
Purpose
  • To develop a numerical simulation using the FLASH
    code to simulate mixing of flulds at the surface
    of a white dwarf star
  • Understanding this mixing will contribute to our
    understanding of novae explosions in binary
    systems containing a white dwarf star

4
What is FLASH?
  • FLASH is a three dimensional hydrodynamics code
    that solves the Euler equations of hydrodynamics
  • FLASH uses an adaptive mesh of points that can
    adjust to areas of the grid that need more
    refinement for increased accuracy
  • FLASH also can account for other physics, such as
    nuclear reactions and gravity

5
What is FLASH?
  • Euler equations of hydrodynamics
  • r/t Ñ rv 0
  • rv/t Ñ rvv ÑP rg
  • rE/t Ñ (rE P) v rv g
  • where
  • E e ½v2

6
What is FLASH?
  • Pressure obtained using equation of state
  • ideal gas
  • P (g - 1)re
  • other equations of state (i.e. for degenerate
    Fermi gases, radiation, etc.)
  • For reactive flows track each species
  • rXl/t Ñ rXlv 0

7
Mixing in Novae
  • What is a nova?
  • novae occur in binary star systems consisting of
    a white dwarf star and a companion star
  • the white dwarf accretes material into an
    accretion disk around it from the companion
  • some of this material ends up in a H-He envelope
    on the surface of the white dwarf

8
Mixing in Novae
  • this material gets heated and compressed by the
    action of gravity
  • at the base of this layer, turbulent mixing mixes
    the stellar composition with the white dwarf
    composition (C, N, O, etc.)
  • temperatures and pressures are driven high enough
    for thermonuclear runaway to occur (via the CNO
    cycle) and the radiation causes the brightness
    increase and blows the layer off

9
Setting Up the Problem
  • Initial Conditions
  • what we want is a stable model of a white dwarf
    star and an accretion envelope in hydrostatic
    equilibrium
  • we get close enough to the surface where
    Cartesian coordinates (x, y, z) and a constant
    gravitational field are valid approximations

10
Setting Up the Problem
  • Hydrostatic Equilibrium
  • to ensure a stable solution we must set up the
    initial model to be in hydrostatic equilibrium,
    meaning v 0 everywhere
  • momentum equation reduces to
  • ÑP rg
  • set this up using finite difference method,
    taking an average of densities

11
Setting Up the Problem
  • Procedure for initial model
  • set a density at the interface
  • set temperature, elemental abundances
  • call equation of state to get pressure
  • iterate hydrostatic equilibrium condition and
    equation of state to get pressure, density, etc.
    in rest of domain

12
Setting Up the Problem
  • Region I 50 C, 50 O, T1 107 K
  • Region II 75 H, 25 He, T2 108 K
  • Density at interface
  • ro 3.4 103 g cm-3

13
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14
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15
Doing the Problem
  • Loading the model into FLASH
  • load the model in and see if the simulation is in
    hydrostatic equilibrium
  • it ISNT!
  • high velocities at interface and boundary
  • begin to examine the model for possible flaws

16
Doing the Problem
  • Question Is the model itself really in
    hydrostatic equilibrium?
  • test the condition, discover that the model is in
    hydrostatic equilibrium to about one part in 1012
  • Question Is the resolution high enough?
  • try increasing number of points read in, increase
    refinement, still no change

17
Doing the Problem
  • Question Is the density jump across the
    interface hurting accuracy?
  • smooth out density jump by linearly changing
    temperature and abundances
  • velocities slightly lower, but still present
  • try this for a number of different sizes of
    smoothing regions, still no change

18
Doing the Problem
  • Check the equation of state
  • the Helmholtz equation of state we were using was
    complex
  • accounts for gas, degenerate electrons, and
    radiation
  • switch to gamma equation of state to see if
    anything improves
  • NO IMPROVEMENT!

19
Movie Time!
  • (maybe)

20
Doing the Problem
  • Two important resolutions
  • there was an error in temperature calculation
    which was caused by a mismatch in precision of
    numerical constants
  • we found that if we used the same number of
    points in FLASH as we did the initial model some
    of the inconsistency was resolved

21
Doing the Problem
  • Which brings us to where we currently are
  • we believe that by our linear interpolation for
    the density is too imprecise
  • we are currently implementing a quadratic
    interpolation for the density

22
Conclusions
  • What have we learned?
  • stability is important
  • the need for there to be a check within FLASH
    itself for hydrostatic equilibrium
  • the need to carefully examine all parts of a code
    to look for possible mistakes
  • consistency!

23
Conclusions
  • Thanks to
  • Mike Zingale and Jonathan Dursi
  • Prof. Don Lamb
  • the ASCI FLASH Center
  • the University of Chicago
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