nonlinear dynamics of self-organized plasmas
TRANSCRIPT
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Nonlinear Dynamics of Self-Organized Plasmas
Richard Fitzpatricka
Institute for Fusion Studies
Department of Physics
University of Texas at Austin
aWork done in collaboration with Paolo Zanca, University of Padua
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Magnetic Fusion
• Nuclear fusion requires plasma temperatures approximately ten
times hotter than centre of sun.
• Conventional confinement via material walls out of question.
• Magnetic fusion aims to confine thermonuclear plasma via
magnetic field. According to standard magnetohydrodynamics
(MHD), plasma tied to magnetic field-lines.
• Magnetic field-lines not rigid. Instabilities can develop which cause
field and plasma to thrash about, leading to loss of confinement.
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Toroidal Pinches
• Toroidal plasma forms single-turn secondary winding of large
transformer circuit.
• Flux-swing in multi-turn primary winding induces toroidal current
in plasma, which generates poloidal magnetic field.
• Toroidal magnetic field generated by currents flowing in external
coils.
• Net result is set of nested toroidal magnetic flux-surfaces on which
plasma is (hopefully) confined.
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field−coil
field−coiltoroidal
poloidal
central solenoid
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flux−surface
magnetic
magnetic
axis
Poloidal Cross−Section
toroidal
field−coil
axistoroidal
plasma
.
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Reversed Field Pinches
• In reversed field pinch (RFP) concept, developed at UKAEA
Harwell, plasma surrounded by close-fitting conducting shell which
“clamps” plasma edge in place.
• Intense internal MHD activity causes relaxation to stable
configuration. In essence, plasma determines its own final state.
Example of self-organized plasma.
• Relaxed state of RFP plasma characterized by reversal of toroidal
magnetic field close to plasma edge.
• J.B. Taylor first to demonstrate that reversed configuration is
minimum energy state of plasma subject to constraints imposed
by close-fitting shell.
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Bθ
00 r
00
1
q =∆ φ∆ θ
r
Bφ
reversal surface
center edge
Magnetic fields Winding number
φ − toroidal angle
θ − poloidal angle
.
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MHD Stability of RFPs
• Taylor relaxed state is stable to all MHD instabilities.
• Unfortunately, real-life RFP plasmas not (quite) in Taylor state:
– Taylor state implies large edge currents. These are prevented
by high resistivity of cold edge plasma.
– Resistive evolution of plasma current profile drives equilibrium
away from Taylor state.
• RFP plasmas subject to multiple, relatively benign, MHD
instabilities, called tearing modes, which:
– Prevent equilibrium from straying too far from Taylor state.
– Degrade plasma confinement.
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Tearing Modes in RFPs
• Tearing mode in RFP plasma identified via its poloidal mode
number, m (number of periods short way around torus), and
toroidal mode number, n (number of periods long way around
torus).
• Tearing mode resonates with magnetic field when its helical pitch
matches that of field. Resonance condition:
m = nq,
where q(r) is magnetic winding number.
• Tearing modes tear and reconnect magnetic field-lines in vicinity
of their resonant surfaces. Convert nested magnetic flux-surfaces
(good confinement) into chaotic mess (poor confinement).
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Dominant Tearing Modes in RFPs
0
reversal surface
0
r
q
0.2
1, 5 1, 71, 6 1, 8
0, 30, 20, 1
• Dominant tearing modes in RFPs are m = 1 modes, resonant in
plasma core, and m = 0 modes, resonant at reversal surface.
• Modes interact via nonlinear coupling:
(0, 1) + (0, 2) → (0, 1) + (0, 3)
(1, 5) + (1, 6) → (0, 1)+(2, 11)
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Slinky Pattern
• Tearing mode amplitudes vary on relatively slow time-scale
determined by plasma resistivity. Phases vary on much shorter
time-scale.
• Tearing modes in RFP spontaneously phase-lock to form toroidally
localized pattern in perturbed magnetic field known as slinky.
• Slinky pattern rotates toroidally in some experiments, but is
stationary in others.
• Stationary slinky pattern causes severe edge loading problem
which limits maximum achievable plasma current.
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edge m=1 magnetic field
tim
e (
ms)
toroidal angle (degrees)
• Data from MST experiment (Madison, WI).
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Critical Questions
• How does nonlinear coupling of tearing modes in RFP plasma lead
to formation of slinky pattern?
• Can we predict properties of slinky pattern without having to
perform many expensive 3D MHD simulations?
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Force Minimization
• Plasma perturbed equation of motion:
ρdv
dt= j × B + µ∇2v.
• At large mode amplitudes, nonlinear j × B force dominates both
inertia and viscosity.
• Maybe phases of tearing modes in plasma arrange themselves so
as to minimize nonlinear j × B force? Can we use this simple idea
to account for formation and properties of slinky pattern?
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m = 0 Modes
• m = 0 modes, resonant at reversal surface, couple nonlinearly and
generate nonlinear j× B force at reversal surface.
• What arrangement of m = 0 phases minimizes net amplitude of
j × B force at reversal surface?
• Answer:
ϕ0,n = nφ0 ∓ π/2,
where ϕ0,n is phase of 0, n mode, and φ0 arbitrary.
• This particular phase arrangement generates two characteristic
mirror-image patterns in m = 0 magnetic field (depending on sign
chosen).
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Predicted m = 0 Magnetic Fields
Upper sign: 15 modes Lower sign: 15 modes
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Observed m = 0 Magnetic Fields
• Data from RFX experiment (Padua). Consistent with upper sign.
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Observed m = 0 Phase Correlations
• Here
d0(k) = ϕ0,k+1 − ϕ0,k − ϕ0,1.
• Theoretical prediction is d0(k) = +π/2.
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m = 1 Modes
• m = 1 modes couple nonlinearly through m = 0 modes and
generate nonlinear j× B forces at resonant surfaces of interacting
modes.
• What arrangement of m = 1 phases minimizes net amplitude of
j × B forces at resonant surfaces?
• Answer:
ϕ1,n = nφ0 − ∆0,
where ϕ1,n is phase of 1, n mode, and ∆0 arbitrary.
• This particular phase arrangement generates toroidally localized
pattern in m = 1 magnetic field.
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Predicted m = 1 Magnetic Fields
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Observed m = 1 Magnetic Fields
• Data from RFX experiment (Padua).
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Observed m = 1 Phase Correlations
• Here
d1(n) = ϕ1,n+1 − ϕ1,n − ϕ0,1.
• Theoretical prediction is d1(n) = +π/2.
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Phase Locking Rules
• RFP plasma is complicated dynamical system consisting of many
tearing modes interacting nonlinearly via three-wave coupling.
• Nevertheless, force minimization principle allows us to accurately
predict properties of final phase-locked state of system.
• Phase locking rules are:
ϕ0,n = nφ0 ∓ π/2,
ϕ1,n = nφ0 − ∆0.
• Phase locking causes toroidally localized pattern in perturbed
magnetic field, centered on φ = φ0.
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Uses of Phase Locking Rules
• Phase locking rules have been successfully used to explain
interaction of slinky pattern with resonant static external magnetic
perturbations.
• This understanding allows us to explain why slinky pattern rotates
in some experiments, but not in others.
• Also allows us to design specific combinations of external
perturbations which can be used to force pattern to rotate, or
even break up pattern altogether.
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Summary
• RFP plasma is complicated, intrinsically 3D, highly nonlinear,
dynamical system.
• Taylor’s hypothesis (minimization of energy at fixed magnetic
helicity) allows us to predict proprieties of relaxed plasma
equilibrium.
• New force minimization hypothesis (minimization of nonlinear
electromagnetic forces via variation of mode phases at fixed mode
amplitudes) allows us to predict properties of final phase locked
state of tearing modes in plasma.
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