2020
DOI: 10.1016/j.cnsns.2020.105289
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INVITED: Slow manifold reduction for plasma science

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Cited by 19 publications
(19 citation statements)
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“…A goal of future work will be to apply our results to infinite dimensional systems, especially systems with slow manifolds such as ideal magnetohydrodynamics, Burby (2017), kinetic magnetohydrodynamics, Burby & Sengupta (2018) and Lorentz loop dynamics, Burby (2020). See Burby & Klotz (2020) for an in-depth discussion of the role of slow manifolds in plasma physics. Just as Cotter & Reich (2004) shows that the long-time persistence of quasigeostrophic balance in non-dissipative geophysical fluid flows may be explained by finding an appropriate adiabatic invariant, adiabatic invariants in these plasma-dynamical systems may explain subtle notions such as the persistence time scale for gyrotropy in strongly magnetized plasmas.…”
Section: Resultsmentioning
confidence: 99%
See 1 more Smart Citation
“…A goal of future work will be to apply our results to infinite dimensional systems, especially systems with slow manifolds such as ideal magnetohydrodynamics, Burby (2017), kinetic magnetohydrodynamics, Burby & Sengupta (2018) and Lorentz loop dynamics, Burby (2020). See Burby & Klotz (2020) for an in-depth discussion of the role of slow manifolds in plasma physics. Just as Cotter & Reich (2004) shows that the long-time persistence of quasigeostrophic balance in non-dissipative geophysical fluid flows may be explained by finding an appropriate adiabatic invariant, adiabatic invariants in these plasma-dynamical systems may explain subtle notions such as the persistence time scale for gyrotropy in strongly magnetized plasmas.…”
Section: Resultsmentioning
confidence: 99%
“…A goal of future work will be to apply our results to infinite dimensional systems, especially systems with slow manifolds such as ideal magnetohydrodynamics, Burby (2017), kinetic magnetohydrodynamics, Burby & Sengupta (2018) and Lorentz loop dynamics, Burby (2020). See Burby & Klotz (2020) for an in-depth discussion of the role of slow manifolds in plasma physics.…”
Section: Resultsmentioning
confidence: 99%
“…The method has been used in particular in fluid dynamics for model-order reduction in different problems, see, e.g. [27,82,109,151,159,180,278], but also in unsteady magnetic dynamos [151] and plasma physics [21]. For conservative or near-conservative systems, a straightforward application of centre manifold is, however, more difficult due to the small (or vanishing) decay rates.…”
Section: Invariant Manifolds For Dynamical Systemsmentioning
confidence: 99%
“…This will be detailed next since it gives the first significant terms in the developments, that can be used for direct comparisons with other methods. In subsequent developments, They also propose to solve (21) numerically. This will be reviewed in Sect.…”
Section: Two-dimensional Invariant Manifoldmentioning
confidence: 99%
“…Mathematically, the formal invariant manifold underlying Vlasov-Poisson, Vlasov-Darwin and higher-order corrections thereof is an example of a slow manifold. The general theory of slow manifolds is reviewed in MacKay ( 2004) for a mathematical audience and in Burby (2020b) for an audience of plasma physicists. Since a slow manifold in a Hamiltonian system necessarily inherits a Hamiltonian structure, it follows immediately that the dark slow manifold in the Vlasov-Maxwell system has a natural Hamiltonian structure.…”
Section: Introductionmentioning
confidence: 99%