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Online Town Hall Meeting Theory & Computation
Modernizing and advancing the understanding of plasma waves: field-theoretical paradigm
I. Y. Dodin
Collaborators:
N. J. Fisch, D. E. Ruiz, C. Liu, I. Barth, P. F. Schmit, A. I. Zhmoginov
Online Town Hall Meeting
02:00 PM – 06:00 PM, 08/05/2015
Frontier: variational methods in plasma wave theory
Why methods?
Methodology is underrepresented in plasma physics but is critical, e.g., for systematization. The size of textbooks cannot grow indefinitely!
Why plasma waves?
Waves play a key role essentially in all aspects of plasma dynamics (RF, laser, quantum). As long as we study plasmas, we have to study waves.
Why variational (field-theoretical) methods?
Lingua franca of modern theoretical physics, can help bridge plasma theory with other disciplines.
Extremely useful for practical calculations.
Robustness and efficacy of modeling plasma waves needs improvement
Challenges in full-wave modeling symplectic integrators* (not in this talk)
Challenges in reduced theories new basic physics (in this talk)
Solution: Find a variational principle and approximate the functional instead of a PDE.
Cause: Equations for E are not natural: complicated, not manifestly conservative... Effects of approximations are hard to predict.
Problem: Numerical and analytical wave models still lack robustness and efficacy.
*e.g., Bridges and Reich, J. Phys. A: Math. Gen. 39, 5287 (2006)
For example, RF codes often produce contradicting results, while ab initio simulations remain too expensive.
Photon wave function & reparameterizations of the wave Lagrangian
Scalar waves in the geometrical-optics ( WKB) approximation:
Point-particle limit (ray equations):
The natural variable describing the wave field in not E but a "photon wave function",
Fundamental physics of waves as dynamics objects (not EM fields) is an open area.
Theory of everything. Applications to quantum particles & classical waves
Fluid Lagrangians are deduced without introducing constraints; e.g., warm (Clebsch), relativistic (Klein-Gordon), quantum (Madelung), Pauli (Takabayasi)…
Application to particles: kinetics and hydrodynamics emerge as field theories without ħ
Example 1: Corrections to ray-tracing equations, new insights to quantum problems
Example 2: Dispersion and dynamics of nonlinear waves
Example 3: Wave kinetics, modulational dynamics, and ponderomotive forces
Application to plasma waves:
Example 1
Improving ray tracing
Extended geometrical optics: polarization effects, not diffraction
Standard ray equations are limited to scalar waves. Vector waves exhibit additional "spin-orbital coupling".
E.g., weakly magnetized cold electron plasma:
Challenge: implement polarization corrections in practical ray-tracing simulations
The basic effect is known from optics, but is more important in plasma due to larger /L.
cf. Littlejohn and Flynn ('91), Libermanand Zeldovich ('92), Onoda et al ('04), Bliokh et al ('08)…
Ruiz and Dodin ('15a, '15b)
Ruiz and Dodin (2015)
The same theory yields a point-particle Lagrangian of an electron with spin. It is the first Lagrangian that is formally deduced from a quantum Lagrangian and captures orbital and spin dynamics simultaneously.
cf. Gaioli & Alvarez ('98), Barut et al ('84-'93), Derbenev & Kondratenko ('73), Plahte ('67), Rubinow & Keller ('63), Pauli ('32), Frenkel ('26)...
Understanding plasma waves yields new insights to quantum problems
Slow fields: the BMT theory is made conservative
Oscillatory fields: ponderomotive Lagrangian of an electron in a vacuum relativistic EM wave, arbitrary de Broglie/EM
Example 2
Ponderomotive forces on classical waves and applications to wave kinetics
Dodin and Fisch, PRL (2014)
Ponderomotive effects on classical waves: geometrical-optics limit
In a modulated medium, the slow dynamics is governed by the time-averaged Lagrangian
Example 2: Photon in modulated plasma
Example 1: Electron as a quantum wave
Photons as polarizable particles that contribute to the dielectric tensor
Suppose a LF modulation wave is coupled with many HF waves. Ponderomotive Hamiltonians enter the self-consistent Lagrangian of the LF wave and determine the effective dielectric tensor
cf. Tsytovich (1970); Bingham et al (1997); Mendonca (2000); Dylov and Fleischer (2008) . . .
Challenge: explore ramifications for wave kinetics, turbulence…
Example: HF photons serve as polarizable particles and can cause Landau damping (corrected theory, applies in inhomogeneous nonstationary plasma, extends beyond GO…)
Example 3
Understanding nonlinear waves (recent developments)
Nonlinear variational theory captures even trapped-particle effects
Nonlinear wave Lagrangian is expressed through oscillation-center (ponderomotive) Hamiltonians
• Hs can be found for any given parameterization of the field. Then wave equations are obtained:
Liu and Dodin, PoP (2015); Dodin, FST (2014); Dodin et al, PRL (2013a); PoP (2012a,b,c); PRL (2011); Schmit et al, PRL (2013b)
• Example: the 50-year-old problem of finding the general shift a0
2 is readily solved!
Challenges: nonlinear dissipation, EM theory, self-consistent reduced models...
Fundamental variational theory of plasma waves as a frontier: summary
Extended geometrical optics: ray bending, insights to quantum problems
Ponderomotive forces on waves and wave kinetics, photons as polarizable particles
Nonlinear waves: unifying nonlinear dispersion relation including both kinetic and fluid effects…
Sample applications discussed in this talk:
Leads to a systematic theory (critical in the long run)
Lingua franca of modern theoretical physics, can help bridge plasma physics with other disciplines
Extremely useful for practical calculations
Importance of a consistent variational formulation:
Challenges:
Rethink basic theory of plasma waves as a wave theory: plasma waves are not just EM fields
Develop symplectic algorithms to practical full-wave modeling of linear RF and other plasma waves
Implement polarization corrections in practical ray-tracing simulations
Explore ramifications in nonlinear waves, wave kinetics, turbulence...
Fundamental theory of plasma waves is an open frontier of great importance.
References
D. E. Ruiz, I. Y. Dodin, First-principle variational formulation of polarization effects in geometrical optics, arXiv:1507.05863.
C. Liu and I. Y. Dodin, Nonlinear frequency shift of electrostatic waves in general collisionless plasma: unifying theory of fluid and kinetic nonlinearities, arXiv:1505.03498, to appear in Phys. Plasmas.
I. Barth, I. Y. Dodin, and N. J. Fisch, Ladder climbing and autoresonant acceleration of plasma waves, arXiv:1504.00399, to appear in Phys. Rev. Lett.
D. E. Ruiz and I. Y. Dodin, Lagrangian geometrical optics of nonadiabatic vector waves and spin particles, arXiv:1503.07829, to appear in Phys. Lett. A.
D. E. Ruiz and I. Y. Dodin, On the correspondence between quantum and classical variational principles, arXiv:1503.07819, to appear in Phys. Lett. A.
I. Y. Dodin and N. J. Fisch, Ponderomotive forces on waves in modulated media, Phys. Rev. Lett. 112, 205002 (2014).
I. Y. Dodin, Geometric view on noneikonal waves, Phys. Lett. A 378, 1598 (2014).
I. Y. Dodin, On variational methods in the physics of plasma waves, Fusion Sci. Tech. 65, 54 (2014).
X. Guan, I. Y. Dodin, H. Qin, J. Liu, and N. J. Fisch, On plasma rotation induced by waves in tokamaks, Phys. Plasmas 20, 102105 (2013).
I. Y. Dodin and N. J. Fisch, Axiomatic geometrical optics, Abraham-Minkowski controversy, and photon properties derived classically, Phys. Rev. A 86, 053834 (2012).
I. Y. Dodin and N. J. Fisch, Fundamental variational theory of plasma waves, Town Hall white paper.
I. Y. Dodin, Plasma science as a science, Town Hall white paper.
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