2017
DOI: 10.1103/physrevfluids.2.114604
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Comparison of forcing functions in magnetohydrodynamics

Abstract: Results are presented of direct numerical simulations of incompressible, homogeneous magnetohydrodynamic turbulence without a mean magnetic field, subject to different mechanical forcing functions commonly used in the literature. Specifically, the forces are negative damping (which uses the large-scale velocity field as a forcing function), a nonhelical random force, and a nonhelical static sinusoidal force (analogous to helical ABC forcing). The time evolution of the three ideal invariants (energy, magnetic h… Show more

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Cited by 13 publications
(12 citation statements)
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References 55 publications
(67 reference statements)
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“…where e 1 · e * 2 = e 1 · k = e 2 · k = 0 and e 1 and e 2 are unit vectors statisfying ik × e 1 = ke 1 and ik × e 2 = −ke 2 [28][29][30]. A(k) and B(k) are variable parameters that allow the injection of helicity to be adjusted; we chose to force nonhelically.…”
Section: Simulationsmentioning
confidence: 99%
See 1 more Smart Citation
“…where e 1 · e * 2 = e 1 · k = e 2 · k = 0 and e 1 and e 2 are unit vectors statisfying ik × e 1 = ke 1 and ik × e 2 = −ke 2 [28][29][30]. A(k) and B(k) are variable parameters that allow the injection of helicity to be adjusted; we chose to force nonhelically.…”
Section: Simulationsmentioning
confidence: 99%
“…In our forced simulations we set k 0 = 5 and forced the velocity field at the largest scales, 1 ≤ k ≤ 2.5. The nature of the forcing function and the forcing length scale do not greatly affect the dynamics [28,32]. We also ran decaying simulations, where we were less interested in the inertial range energy spectra and more interested in RST, so we set the peak at k 0 = 40.…”
Section: Simulationsmentioning
confidence: 99%
“…In the dissipation range, we observe a significant level of the relative cross helicity, as well as reversal of cross helicity as we traverse from large scales to small scales. This feature has been reported earlier in [16], but it was not analysed in detail. The presence of relatively large levels of relative cross helicity in the dissipation range is in marked contrast to the vanishing kinetic helicity in dissipative range of hydrodynamic turbulence.…”
Section: Discussionmentioning
confidence: 52%
“…Finally, E b is approaching a statistically stationary state. That is, it enters the saturated stage (III) which at unity magnetic Prandtl number and sufficiently large Re is characterized by the ratios of the dissipation rates ε b /(ε u +ε b ) 0.7 and energies E b /(E u +E b ) 0.25 [41][42][43][44]. Our data in stage (III) is consistent with these ratios, as can be seen from the values listed in table II, where a summary of the dynamo runs in the kinematic (I), nonlinear (II) and saturated (III) stages is provided.…”
Section: Description Of the Datasetmentioning
confidence: 99%