Formation of solitary zonal structures via the modulational instability of drift waves

Zhou, Yao; Zhu, Hongxuan; Dodin, I. Y.

doi:10.1088/1361-6587/ab16a8

Cited by 14 publications

(29 citation statements)

References 65 publications

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“…in simulations of DW turbulence in a linear device [37].) Note that the propagating structures observed here are different from the DW-ZF solitons generated in the largeα limit [38]. They may be related to those seen in simulations of subcritical turbulence [39][40][41].…”

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confidence: 67%

Theory of the Tertiary Instability and the Dimits Shift from Reduced Drift-Wave Models

2020

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Tertiary modes in electrostatic drift-wave turbulence are localized near extrema of the zonal velocity U (x) with respect to the radial coordinate x. We argue that these modes can be described as quantum harmonic oscillators with complex frequencies, so their spectrum can be readily calculated. The corresponding growth rate γTI is derived within the modified Hasegawa-Wakatani model. We show that γTI equals the primary-instability growth rate plus a term that depends on the local U ; hence, the instability threshold is shifted compared to that in homogeneous turbulence. This provides a generic explanation of the well-known yet elusive Dimits shift, which we find explicitly in the Terry-Horton limit. Linearly unstable tertiary modes either saturate due to the evolution of the zonal density or generate radially propagating structures when the shear |U | is sufficiently weakened by viscosity. The Dimits regime ends when such structures are generated continuously.Drift-wave (DW) turbulence plays a significant role in fusion plasmas and can develop from various "primary" instabilities [1][2][3][4][5][6][7]. However, having their linear growth rate γ PI above zero is not enough to make plasma turbulent, because the "secondary" instability can suppress turbulence by generating zonal flows (ZFs) [5][6][7][8][9][10][11][12]; hence, the threshold for the onset of turbulence is modified compared to the linear theory. This constitutes the so-called Dimits shift [12][13][14][15][16][17], which has been attracting attention for two decades. The finite value of the Dimits shift is commonly attributed to the "tertiary" instability (TI) [5], and some theories of the TI have been proposed [5,[15][16][17][18][19][20]. However, basic understanding and generic description of the TI and the Dimits shift have been elusive.Here, we propose a simple yet quantitative theory of the TI using the modified Hasegawa-Wakatani equation (mHWE) [2,16] as a base turbulence model. We clarify several misconceptions regarding the TI, and we explicitly derive the Dimits shift in the limit corresponding to the Terry-Horton model [15,21]. Our approach is also applicable to other DW models, such as ion-temperaturegradient (ITG) turbulence [5], as discussed towards the end. Furthermore, we explain TI's role in two types of predator-prey (PP) oscillations, in determining the characteristic ZF scale in the Dimits regime, and in transition to the turbulent state.Model equations.-The mHWE [2, 16] is a slab model of two-dimensional electrostatic turbulence with a uniform magnetic field B = Bẑ. Turbulence is considered on the plane (x, y), where x is the radial coordinate and y is the poloidal coordinate. The model describes ϕ and n, which are fluctuations of the electric potential and density, respectively. Ions are assumed cold while electrons have finite temperature T e . The plasma is assumed to have an equilibrium density profile n 0 (x) parameterized by a constant κ . = a/L n , where a is the system length and L n . = (−n 0 /n 0 ) −1 . (We use . = to denote...

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confidence: 67%

Theory of the Tertiary Instability and the Dimits Shift from Reduced Drift-Wave Models

2020

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“…This is understood from the fact that although a primary instability and dissipation would contribute additional terms in our WKE model (section 2.5), they would not affect the drifton phase-space trajectories that we discuss here. For example, in a recent study on the formation of solitary zonal structures [50], we demonstrate numerically that the structure formation is not significantly affected by external forcing and dissipation. Also, the trapping of driftons near phase-space equilibria, which will be discussed in section 4.1, can help explain the localization of DW activity reported recently within the Hasegawa-Wakatani model in [51] and may explain the results of some earlier studies of gyrokinetic plasmas [3, 52].…”

Section: Basic Equations 21 Hasegawa-mima Equationmentioning

confidence: 62%

“…The striped structure in figure (b) is due to the interference between the shown trapped distribution and a similar distribution on the next spatial period (not shown). Such structures are discussed in further detail in [50]. (figure (a)) and the Φ 0 =0.35 (figure (b)) case in figure 6(d).…”

Section: Difference Between the Ql And Nl Modelsmentioning

confidence: 86%

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Nonlinear saturation and oscillations of collisionless zonal flows

2019

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In homogeneous drift-wave turbulence, zonal flows (ZFs) can be generated via a modulational instability (MI) that either saturates monotonically or leads to oscillations of the ZF energy at the nonlinear stage. This dynamics is often attributed as the predator-prey oscillations induced by ZF collisional damping; however, similar dynamics is also observed in collisionless ZFs, in which case a different mechanism must be involved. Here, we propose a semi-analytic theory that explains the transition between the oscillations and saturation of collisionless ZFs within the quasilinear Hasegawa-Mima model. By analyzing phase-space trajectories of DW quanta (driftons) within the geometrical-optics (GO) approximation, we argue that the parameter that controls this transition is N∼γ MI /ω DW , where γ MI is the MI growth rate and ω DW is the linear DW frequency. We argue that at N=1, ZFs oscillate due to the presence of so-called passing drifton trajectories, and we derive an approximate formula for the ZF amplitude as a function of time in this regime. We also show that at N 1, the passing trajectories vanish and ZFs saturate monotonically, which can be attributed to phase mixing of higher-order sidebands. A modification of N that accounts for effects beyond the GO limit is also proposed. These analytic results are tested against both quasilinear and fully-nonlinear simulations. They also explain the earlier numerical results by Connaughton et al (2010 J. Fluid Mech. 654 207) and Gallagher et al (2012 Phys. Plasmas 19 122115) and offer a different perspective on what the control parameter actually is that determines the transition from the oscillations to saturation of collisionless ZFs.

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“…So far, it was successfully applied to manifestly quantumlike systems, such as those governed by the nonlinear Schrödinger equation [20][21][22][23][24][25][26] and the Klein-Gordon equation [27,28]. More recently, the same method was extended to drift-wave and Rossby-wave turbulence, where the wave function is governed by a Hamiltonian very different from a usual quantum particles, and a number of intriguing effects were identified as a result [29][30][31][32][33]. But this application is still limited to scalar waves, while the Wigner-Moyal approach could be useful also in more complex systems, where the wave function is a large-dimensional vector comprised of diverse fields (i.e., not just the electromagnetic field, as usual).…”

Section: Introductionmentioning

confidence: 99%

Structure formation in turbulence as an instability of effective quantum plasma

2020

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Structure formation in turbulence is effectively an instability of "plasma" formed by fluctuations serving as particles. These "particles" are quantumlike; namely, their wavelengths are non-negligible compared to the sizes of background coherent structures. The corresponding "kinetic equation" describes the Wigner matrix of the turbulent field, and the coherent structures serve as collective fields. This formalism is usually applied to manifestly quantumlike or scalar waves. Here, we extend it to compressible Navier-Stokes turbulence, where the fluctuation Hamiltonian is a five-dimensional matrix operator and diverse modulational modes are present. As an example, we calculate these modes for a sinusoidal shear flow and find two modulational instabilities. One of them is specific to supersonic flows, and the other one is a Kelvin-Helmholtz-type instability that is a generalization of the known zonostrophic instability. This work serves as a stepping stone toward improving the understanding of magnetohydrodynamic turbulence, which can be approached similarly.

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Formation of solitary zonal structures via the modulational instability of drift waves

Cited by 14 publications

References 65 publications

Theory of the Tertiary Instability and the Dimits Shift from Reduced Drift-Wave Models

Theory of the Tertiary Instability and the Dimits Shift from Reduced Drift-Wave Models

Nonlinear saturation and oscillations of collisionless zonal flows

Structure formation in turbulence as an instability of effective quantum plasma

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