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Burning Plasma Simulations: Edge Issues

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Title: Burning Plasma Simulations: Edge Issues


1
Burning Plasma Simulations Edge Issues
  • D. P. Coster
  • Max Planck Institute for Plasma Physics,EURATOM
    Association, Garching, Germany

2
Outline
  • Why are edge issues important for burning plasma
    simulations?
  • All the external sources pass through the edge
  • The non-neutron waste products are all removed
    via the edge
  • Much of the performance of the core is determined
    by the edge
  • The edge provides constraints on the core

3
Outline
  • Why are edge issues important for burning plasma
    simulations?
  • All the external sources pass through the edge
  • Particle
  • Gas puff
  • Pellets
  • NBI
  • Energy
  • NBI
  • RF
  • The non-neutron waste products are all removed
    via the edge
  • Much of the performance of the core is determined
    by the edge
  • The edge provides constraints on the core

4
Outline
  • Why are edge issues important for burning plasma
    simulations?
  • All the external sources pass through the edge
  • The non-neutron waste products are all removed
    via the edge
  • Particles
  • D, T
  • He
  • Energy
  • Much of the performance of the core is determined
    by the edge
  • The edge provides constraints on the core

5
Outline
  • Why are edge issues important for burning plasma
    simulations?
  • All the external sources pass through the edge
  • The non-neutron waste products are all removed
    via the edge
  • Much of the performance of the core is determined
    by the edge
  • H-mode barrier
  • He concentration
  • Impurities
  • The edge provides constraints on the core

6
Outline
  • Why are edge issues important for burning plasma
    simulations?
  • All the external sources pass through the edge
  • The non-neutron waste products are all removed
    via the edge
  • Much of the performance of the core is determined
    by the edge
  • The edge provides constraints on the core
  • Minimum separatrix density
  • ELMs
  • Particle throughput

7
What tools are currently available?
  • Mainly a European perspective
  • Edge transport codes
  • Global (in the sense of whole domain, consistent)
  • SOLPS (B2-Eirene)
  • EDGE2D-NIMBUS
  • Fluid plasma (2d)
  • Kinetic neutral (2d or 3d)
  • Multiple species
  • Local (limited domain, against a fixed
    background)
  • ERO
  • Kinetic trace impurities
  • 2d/3d
  • ASCOT
  • Fast ions or electrons
  • PIC codes

8
Global codes, I
  • Fluid plasma (2d)
  • kinetic plasma effects not properly treated
  • Flux limiters
  • Should we investigate fluid/kinetic hybrids?
  • 2d
  • Ignore 3D effects
  • Localised recycling, sources etc.
  • Multiple species
  • Mixed material issues (later)

Th. Pütterich
9
Global codes, II
  • Fluid plasma (2d), cont
  • Solution domain somewhat limited
  • Doesnt extend all the way to the vacuum vessel
  • What are the appropriate boundary conditions
    there?
  • Implications for
  • heat/particle loads in main vessel
  • Sources of impurities

10
Global codes, III
  • Kinetic neutral (2d or 3d)
  • Kinetic coupling to a Monte-Carlo code
  • More accurate, slower
  • Monte-Carlo Noise
  • (Fluid usually not full Navier-Stokes
  • Not as accurate
  • Own temperature?)
  • Still discussion of role of physics
  • He elastic collisions
  • Hydrocarbon break up chains
  • Vibrational excitations
  • Often details of bypasses, wall out-gassing
    neglected
  • Neutral-neutral collisions and optically thick
    regions

11
Some issues, I
  • Impurities
  • Intrinsically produced
  • Somewhat simplified erosion/deposition models
  • Plasma solution domain usually doesnt extend to
    vacuum vessel
  • Problem with main chamber sources
  • PSI models usually too simple
  • Usually not affected by the plasma in the
    simulations
  • Heating
  • Out-gassing/absorption
  • Isotope exchange
  • ELM target cooling with Ar at inner target
  • Hydrocarbon chemistry including T co-deposition
  • How can we improve them?

Th. Pütterich
12
Some issues, I solution path
  • Effects can be studies using local codes
  • ERO
  • Local erosion / deposition analysis
  • Detailed model for processes
  • Including CxDy
  • If effects are important need to, either
  • Couple to global code
  • Incorporate physics in global code

A. Kirschner
13
Some issues, II
  • Effects of fast particles(?)
  • Differences in energy seen by Langmuir probes and
    Thermography?
  • Look at with kinetic codes
  • ASCOT
  • Monte-Carlo treatment of fast ions or fast
    electrons
  • PIC
  • Problem with time-space scales (particularly if
    more than one space dimension)
  • Need to have recycling physics

Chankin, SOLPS modelling of ASDEX-U H-mode
Plasma, Edge Physics Forum, Jan 2005
Unpuffed, H-mode, AUG
14
Some issues, III
  • Transport coefficients are inputs to the global
    (and local) codes
  • Need 1st principles treatment of radial transport
  • 3 options
  • Parametrize radial and poloidal dependence of
    transport coefficients
  • Non-diffusive nature ( pinches)
  • Couple transport and turbulence codes
  • Move all the physics currently in the transport
    codes into the turbulence codes

Nishimura (while a PostDoc at IPP)
15
Some issues, IV
  • Drifts
  • Still not complete agreement on the equations to
    be implemented
  • Not nearly as robust as the non-drift versions
  • Often have additional time-step limitations
  • Sometimes have problems with extending to far
    into the core
  • Sometimes have problems with reduces solution
    domain in terms of plasma parameters
  • Need to develop a technique for moving from drift
    treatment (2d) to a neoclassical (1d radial)
    treatment

16
Integration
  • Edge with core
  • Edge with PFC

17
Integration
  • Edge with core
  • Couple core and edge
  • COCONUT
  • JETTO-SANCO-EDGE2D-NIMBUS
  • Add core physics to edge codes
  • SOLPS efforts are a start
  • Edge with PFC

Fichtmueller et al, EPTSW
Buerbaumer, Bonnin
18
Integration, II
  • Edge with core
  • Source from ASTRA
  • Use B2.5-I to fit to exp. (Y.P. Chen)
  • Can then use to examine W erosion (Kukushkin)
  • Used as a starting point for ELM simulations
  • Or for disruptions (Konz)
  • Edge with PFC

2
1
4
3
19
Integration
  • Edge with core
  • Edge with PFC
  • Couple edge codes
  • globaland local
  • Add physics from local codes to global codes

20
New developments
  • Working towards more integrated models
  • Integrating plasma and plate
  • SOLPS5-B2
  • Fluid neutrals
  • Thermal model for the plate ???
  • Latest Roth chemical sputtering formula
  • Working towards modelling mixed materials

21
New developments
  • Add accounting of erosion and deposition (B2 side
    only so far)
  • Added a simple mixed materials model


Without re-erosion of deposited material
With re-erosion of deposited material

DCHe, SOLPS-B2, AUG
22
New developments
  • Add accounting of erosion and deposition (B2 side
    only so far)
  • Added a simple mixed materials model
  • Can now treat Be main chamber wall and C divertor
    plates
  • New time-scales!

DCHeBe, SOLPS-B2, AUG
23
Summary
  • Need to think about the edge for Burning Plasma
    Simulations
  • Progress is being made
  • But we still have a way to go!
  • Challenges
  • The same as more many other areas
  • Time-scales
  • Space-scales
  • Dimensionality
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