Canonical symplectic particle-in-cell method for long-term large-scale simulations of the Vlasov–Maxwell equations

In this paper, we develop Hamiltonian particle-in-cell methods for Vlasov-Maxwell equations by applying conforming finite element methods in space and splitting methods in time. For the spatial discretisation, the criteria for choosing finite element spaces are presented such that the semi-discrete system possesses a discrete non-canonical Poisson structure. We apply a Hamiltonian splitting method to the semi-discrete system in time, then the resulting algorithm is Poisson preserving and explicit. The conservative properties of the algorithm guarantee the efficient and accurate numerical simulation of the Vlasov-Maxwell equations over long-time.

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“…In Ref. 24, canonical symplectic methods are developed by discretising the canonical Poisson bracket directly.…”

Section: Introductionmentioning

confidence: 99%

Hamiltonian particle-in-cell methods for Vlasov-Maxwell equations

et al. 2016

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“…To obtain an explicit scheme with high efficiency, here we choose the Euler-symplectic method, which can be expressed by [9,17] …”

Section: Construction Of Lccsamentioning

confidence: 99%

“…It is also feasible to canonicalize the gyro-center equations to construct canonical symplectic algorithms for time-independent magnetic fields [16]. The Particle-in-Cell (PIC) method, known as the first principle simulation method for plasma systems, has been reconstructed by the use of different symplectic methods, including variational symplectic method, canonical symplectic method, and non-canonical symplectic method [6][7][8][9]. Theoretically, symplectic methods impose numerical results with a set of constrains, the number of which is determined by the freedom degrees of the systems [9,17], by preserving the global symplectic structure of the system.…”

Section: Introductionmentioning

confidence: 99%

“…The Particle-in-Cell (PIC) method, known as the first principle simulation method for plasma systems, has been reconstructed by the use of different symplectic methods, including variational symplectic method, canonical symplectic method, and non-canonical symplectic method [6][7][8][9]. Theoretically, symplectic methods impose numerical results with a set of constrains, the number of which is determined by the freedom degrees of the systems [9,17], by preserving the global symplectic structure of the system. Correspondingly, the global relative errors of motion constants can be restricted to bounded small values, which enable symplectic algorithms to retain many key properties of the origin continuous systems.…”

Section: Introductionmentioning

confidence: 99%

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Lorentz covariant canonical symplectic algorithms for dynamics of charged particles

2016

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In this paper, the Lorentz covariance of algorithms is introduced. Under Lorentz transformation, both the form and performance of a Lorentz covariant algorithm are invariant. To acquire the advantages of symplectic algorithms and Lorentz covariance, a general procedure for constructing Lorentz covariant canonical symplectic algorithms (LCCSA) is provided, based on which an explicit LCCSA for dynamics of relativistic charged particles is built. LCCSA possesses Lorentz invariance as well as long-term numerical accuracy and stability, due to the preservation of discrete symplectic structure and Lorentz symmetry of the system. For situations with time-dependent electromagnetic fields, which is difficult to handle in traditional construction procedures of symplectic algorithms, LCCSA provides a perfect explicit canonical symplectic solution by implementing the discretization in 4-spacetime. We also show that LCCSA has built-in energy-based adaptive time steps, which can optimize the computation performance when the Lorentz factor varies.

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“…The development of geometric algorithms for these systems can be challenging. However, recently significant advances have been achieved in the development of structure preserving geometric algorithms for charged particle dynamics [37][38][39][40][41][42][43][44][45][46][47][48][49][50], the Vlasov-Maxwell systems [3,4,[51][52][53][54][55][56][57][58][59][60][61], compressible ideal MHD [62,63], and incompressible fluids [64,65]. All of these methods have demonstrated unparalleled long-term numerical accuracy and fidelity compared with conventional methods.…”

Section: Introductionmentioning

confidence: 99%

Explicit high-order noncanonical symplectic algorithms for ideal two-fluid systems

et al. 2016

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An explicit high-order noncanonical symplectic algorithm for ideal two-fluid systems is developed.The fluid is discretized as particles in the Lagrangian description, while the electromagnetic fields and internal energy are treated as discrete differential form fields on a fixed mesh. With the assistance of Whitney interpolating forms [1][2][3], this scheme preserves the gauge symmetry of the electromagnetic field, and the pressure field is naturally derived from the discrete internal energy.The whole system is solved using the Hamiltonian splitting method discovered by He et al. [4], which was been successfully adopted in constructing symplectic particle-in-cell schemes [3]. Because of its structure preserving and explicit nature, this algorithm is especially suitable for large-scale simulations for physics problems that are multi-scale and require long-term fidelity and accuracy.The algorithm is verified via two tests: studies of the dispersion relation of waves in a two-fluid plasma system and the oscillating two-stream instability.

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Canonical symplectic particle-in-cell method for long-term large-scale simulations of the Vlasov–Maxwell equations

Cited by 102 publications

References 39 publications

Hamiltonian particle-in-cell methods for Vlasov-Maxwell equations

Hamiltonian particle-in-cell methods for Vlasov-Maxwell equations

Lorentz covariant canonical symplectic algorithms for dynamics of charged particles

Explicit high-order noncanonical symplectic algorithms for ideal two-fluid systems

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