Hostname: page-component-cd9895bd7-q99xh Total loading time: 0 Render date: 2024-12-25T02:46:57.121Z Has data issue: false hasContentIssue false

Nonlinear reversed shear Alfvén eigenmode saturation due to spontaneous zonal current generation

Published online by Cambridge University Press:  22 September 2021

Shizhao Wei
Affiliation:
Institute for Fusion Theory and Simulation and Department of Physics, Zhejiang University, Hangzhou 310027, PR China
Tao Wang
Affiliation:
Institute for Fusion Theory and Simulation and Department of Physics, Zhejiang University, Hangzhou 310027, PR China Center for Nonlinear Plasma Science and ENEA C. R. Frascati, Frascati, Italy
Ningfei Chen
Affiliation:
Institute for Fusion Theory and Simulation and Department of Physics, Zhejiang University, Hangzhou 310027, PR China
Zhiyong Qiu*
Affiliation:
Institute for Fusion Theory and Simulation and Department of Physics, Zhejiang University, Hangzhou 310027, PR China Center for Nonlinear Plasma Science and ENEA C. R. Frascati, Frascati, Italy
*
Email address for correspondence: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

General nonlinear equations describing reversed shear Alfvén eigenmode (RSAE) self-modulation via zero-frequency zonal structure (ZFZS) generation are derived using nonlinear gyrokinetic theory, which are then applied to study the spontaneous ZFZS excitation as well as RSAE nonlinear saturation. It is found that both electrostatic zonal flow and electromagnetic zonal current can be preferentially excited by finite-amplitude RSAE, depending on specific plasma parameters. The modification to local shear Alfvén wave continuum is evaluated using the derived saturation level of zonal current, which is shown to play a comparable role in saturating RSAE with the ZFZS scattering.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press

1. Introduction

Future tokamak-based fusion power plants and experimental devices towards this goal (e.g. the ITER; Tomabechi et al. Reference Tomabechi, Gilleland, Sokolov and Toschi1991) are expected to operate at steady state with a substantial non-inductive current fraction (Gormezano et al. Reference Gormezano2007), which generally renders a reversed shear scenario (Huang et al. Reference Huang2020). In this circumstance, the reversed shear Alfvén eigenmode (RSAE; also known as Alfvén cascade) is frequently observed (Sharapov et al. Reference Sharapov, Testa, Alper, Borba, Fasoli, Hawkes, Heeter, Mantsinen and Hellermann2001) as driven unstable by energetic particles (EPs) (Zonca et al. Reference Zonca, Briguglio, Chen, Dettrick, Fogaccia, Testa and Vlad2002; Fasoli et al. Reference Fasoli, Gormenzano, Berk, Breizman, Briguglio, Darrow, Gorelenkov, Heidbrink, Jaun, Konovalov, Nazikian, Noterdaeme, Sharapov, Shinohara, Testa, Tobita, Todo, Vlad and Zonca2007; Chen et al. Reference Chen2014; Chen & Zonca Reference Chen and Zonca2016) in present-day tokamaks, and is expected to play significant roles in future reactors (Wang et al. Reference Wang, Qiu, Zonca, Briguglio, Fogaccia, Vlad and Wang2018), in transporting fusion alpha particles to the tokamak edge (Wang et al. Reference Wang, Wang, Briguglio, Qiu, Vlad and Zonca2019), which has deleterious effects on plasma self-heating, and may damage the plasma-facing components (Ding et al. Reference Ding, Pitts, Borodin, Carpentier, Ding, Gong, Guo, Kirschner, Kocan, Li, Luo, Mao, Qian, Stangeby, Wampler, Wang and Wang2015). The RSAE is a branch of the shear Alfvén wave (SAW) eigenmode localized radially near the minimum of the safety factor $q$-profile (Sharapov et al. Reference Sharapov, Alper, Berk, Borba, Breizman, Challis, Fasoli, Hawkes, Hender, Mailloux, Pinches and Testa2002), which is denoted as $q_{\min }$. The lowest-order RSAE frequency in the incompressible limit, $\omega \simeq k_{\parallel }v_{A}\simeq |n-m/q_{\min }|v_{A}/R$, reflects the sensitive dependence on the instantaneous $q_{\min }$ value for given toroidal/poloidal mode numbers $n$/$m$, and this feature can be used in $q$-profile measurement, i.e. magnetohydrodynamic (MHD) spectroscopy (Fasoli et al. Reference Fasoli, Testa, Sharapov, Berk, Breizman, Gondhalekar, Heeter and Mantsinen2002; Chen et al. Reference Chen2014). Here, $k_{\parallel }$ is the wavenumber parallel to the equilibrium magnetic field $\boldsymbol B$, $v_{A}$ is the Alfvén speed and $R$ is the major radius. Typically, RSAEs are dominated by one or two poloidal harmonics, with the radial width $\propto \sqrt {q/(r^{2}_{0}q'')}$ (see section III of Zonca et al. (Reference Zonca, Briguglio, Chen, Dettrick, Fogaccia, Testa and Vlad2002)) with $r_{0}$ being the radial location of $q_{\min }$ and $q''\equiv \partial ^2_{r}q$. Despite the fairly good understanding of the linear physics, the nonlinear dynamics of RSAE is still interesting and valuable to research, especially in view of the EP as well as thermal particle transport induced by the associated electromagnetic field perturbations (Wang et al. Reference Wang, Wang, Briguglio, Qiu, Vlad and Zonca2019Reference Wang, Qiu, Zonca, Briguglio and Vlad2020; Shi et al. Reference Shi, Qiu, Chen, Wang, Shi, Yu, Yang, Zhong, Jiang, Ji, Yang, Xu and Duan2020; Wei et al. Reference Wei, Wang, Shi, Chen, Chen and Qiu2021). The transport rate is closely related to the perturbation amplitude (Chen Reference Chen1999; Zonca et al. Reference Zonca, Chen, Falessi and Qiu2021); and in reactor-relevant cases with many SAWs simultaneously driven unstable by EPs, the EP orbit could become chaotic and eventually lost in the presence of many low-amplitude SAWs (threshold value $\delta B/B\sim {O}(10^{-4})$) (White et al. Reference White, Gorelenkov, Heidbrink and Zeeland2010a,Reference White, Gorelenkov, Heidbrink and Zeelandb). Thus, the assessment of the nonlinear RSAE saturation mechanism and amplitude plays a crucial role in evaluating the operation scenario and the EP confinement property.

In general, the channels of SAW nonlinear saturation can be classified into two routes, namely wave–particle nonlinear interactions and wave–wave nonlinear couplings (Berk & Breizman Reference Berk and Breizman1990; Chen & Zonca Reference Chen and Zonca2013Reference Chen and Zonca2016; Zonca et al. Reference Zonca, Chen, Briguglio, Fogaccia, Vlad and Wang2015). The former focuses on the perturbation to the resonant EP phase-space distribution function by finite-amplitude SAWs (Berk & Breizman Reference Berk and Breizman1990; Zonca et al. Reference Zonca, Chen, Briguglio, Fogaccia, Vlad and Wang2015), and has been widely investigated using numerical simulations, as reviewed in Chen & Zonca (Reference Chen and Zonca2016) and Lauber (Reference Lauber2013). By contrast, the latter is relatively less explored. Most previous analytical works considered the toroidal Alfvén eigenmode (TAE) (Cheng, Chen & Chance Reference Cheng, Chen and Chance1985) as a paradigm case, including saturation via ion-induced scattering (Hahm & Chen Reference Hahm and Chen1995; Qiu, Chen & Zonca Reference Qiu, Chen and Zonca2019a), nonlinear modification to the SAW continuum structure (Zonca et al. Reference Zonca, Romanelli, Vlad and Kar1995; Chen et al. Reference Chen, Zonca, Santoro and Hu1998), the spontaneous generation of zero-frequency zonal structures (ZFZS) (Chen & Zonca Reference Chen and Zonca2012; Qiu, Chen & Zonca Reference Qiu, Chen and Zonca2016aReference Qiu, Chen and Zonca2017) as well as geodesic acoustic mode (Qiu et al. Reference Qiu, Chen, Zonca and Chen2018aReference Qiu, Chen, Zonca and Chen2019b). Since the RSAEs are expected to be prevalent in future steady-state burning plasmas, RSAE saturation via wave–wave nonlinearity deserves special attention. In particular, the toroidally symmetric zonal field structures (Zonca et al. Reference Zonca, Chen, Falessi and Qiu2021), including the ZFZS, are well known to play important roles in regulating drift wave turbulences (Lin et al. Reference Lin, Hahm, Lee, Tang and White1998; Hahm et al. Reference Hahm, Beer, Lin, Hammett, Lee and Tang1999; Chen, Lin & White Reference Chen, Lin and White2000; Diamond et al. Reference Diamond, Itoh, Itoh and Hahm2005) including drift Alfvén waves, and thus leading to cross-scale couplings (Zonca et al. Reference Zonca, Chen, Briguglio, Fogaccia, Milovanov, Qiu, Vlad and Wang2015a) and nonlinear saturation via scattering of drift waves to the short-radial-wavelength regime (or shearing in some literature). In this work, spontaneous ZFZS excitation by RSAE modulational instability is analysed using nonlinear gyrokinetic theory.

As noted above, the spontaneous excitation of ZFZS by TAE is discussed in Chen & Zonca (Reference Chen and Zonca2012). It is shown that under certain conditions, the zonal current (ZC) is preferentially excited over the electrostatic zonal flow (ZF), with the branch ratio of ZF/ZC excitation determined by various geometry effects, including the breaking of pure Alfvénic state by toroidicity and neoclassical shielding of ZF (Rosenbluth & Hinton Reference Rosenbluth and Hinton1998). In contrast to the TAE case, it is shown in Qiu, Chen & Zonca (Reference Qiu, Chen and Zonca2016b) that for beta-induced Alfvén eigenmode (BAE), the excitation of ZF generally dominates, due to the $|k_{\parallel }v_{A}/\omega |\ll 1$ ordering. For the case of RSAE analysed herein, its frequency is sensitively determined by the value of $q_{\min }$ and the underlying values of toroidal/poloidal mode numbers $n$/$m$, and generally sweeps between the typical BAE to TAE frequency ranges. It is shown that depending on the specific plasma parameters including $k_{\parallel }$, both ZC and ZF generation may dominate, and the previous conclusions on TAE (Chen & Zonca Reference Chen and Zonca2012) and BAE (Qiu et al. Reference Qiu, Chen and Zonca2016b) can be recovered as limiting cases of the general nonlinear dispersion relation derived without assuming specific plasma parameters.

We note that several nonlinear processes, with comparable cross-sections, may be comparably important in saturating Alfvén eigenmode, as addressed in Qiu et al. (Reference Qiu, Chen, Zonca and Chen2018b). In particular, a channel unique for RSAE saturation is proposed in this work. Due to the ZC and the associated perturbed poloidal magnetic field generation, the $q$-profile is modulated, which leads to the modification of the local SAW continuum in the vicinity of $q_{\min }$, and consequently to RSAE saturation. The relevance of this channel to RSAE nonlinear saturation is analysed and evaluated.

This remainder of this paper is arranged as follows. In § 2, the theoretical model is given. In § 3, the general nonlinear equations describing RSAE evolution and ZFZS excitation are derived. Section 4 is devoted to a study of the linear growth stage of the modulational instability; and the nonlinear saturation of RSAE via ZFZS scattering is investigated in § 5. Finally, brief conclusion and discussion are given in § 6.

2. Theoretical model

The nonlinear evolution of this system is studied using the standard nonlinear perturbation theory, considering a shifted circular tokamak equilibrium described by a set of field-aligned flux coordinates $(r, \theta , \varphi )$. The perturbed fields are represented by two field variables, namely the electrostatic potential $\delta \phi$ and the parallel component of vector potential $\delta A_{\parallel }$, while the parallel magnetic field fluctuation $\delta B_{\parallel }$ is suppressed, consistent with $\beta \ll 1$ ordering of typical laboratory plasmas. Here, $\beta$ is the ratio of thermal to magnetic pressures. For convenience, $\delta A_{\parallel }$ is replaced by $\delta \psi \equiv \omega \delta A_{\parallel }/(ck_{\parallel })$, such that the ideal MHD limit, i.e. vanishing parallel electric field fluctuation $\delta E_{\parallel }$, corresponds to simply $\delta \phi =\delta \psi$. In this work, it is assumed that the RSAE is excited by a source outside this nonlinear system, such as EPs, and the nonlinear coupling is dominated by bulk plasma contribution. For the cases with EPs contributing significantly to nonlinear ZFZS generation (Todo, Berk & Breizman Reference Todo, Berk and Breizman2010; Biancalani et al. Reference Biancalani, Bottino, Lauber, Mishchenko and Vannini2020), interested readers may refer to Qiu et al. (Reference Qiu, Chen and Zonca2016aReference Qiu, Chen and Zonca2017) for more systematic discussions. To start with, we consider the two-field coupled system which consists of a RSAE (subscript ‘R’) and ZFZS (subscript ‘Z’), i.e. $\delta \phi =\delta \phi _{R}+\delta \phi _{Z}$ with $\delta \phi _{R}=\delta \phi _{0}+\delta \phi _{0^{*}}$. Here, $\delta \phi _{0}$ represents the RSAE with positive real frequency and $\delta \phi _{0^{*}}$ represents the counterpart with negative real frequency, of which there may be a rich spectrum of different radial eigenstates.

Considering the reactor-relevant parameter regime with $nq\gg 1$, the ballooning mode representation (Connor, Hastie & Taylor Reference Connor, Hastie and Taylor1978) for theRSAE is adopted:

(2.1)\begin{equation} \delta\phi_{0} = A_{0}\, \textrm{e}^{\textrm{i}(n\phi-m_{0}\theta-\omega_{0}t)}\, \textrm{e}^{\textrm{i}\int\hat{k}_{r,0}\, \textrm{d} r}\sum_{j}\, \textrm{e}^{-\textrm{i}j\theta}\varPhi_{0}(x-j)+\textrm{c.c.} \end{equation}

Here, $m=m_{0}+j$ with $m_{0}$ being the reference poloidal mode number, $x\equiv nq-m_{0}$, $\varPhi _{0}$ is the parallel mode structure with typical radial extension comparable to the distance between neighbouring mode rational surfaces, $A_{0}$ is the mode envelope amplitude and $\hat {k}_{r,0}$ is the radial envelope wavenumber accounting for the slowly varying radial structures. Note that the RSAE is typically characterized by one dominant poloidal harmonic, while multiple sub-dominant poloidal harmonics exist due to toroidicity. Furthermore, $\int |\varPhi _{0}|^{2}{\textrm {d}\kern0.06em x}=1$ is used as normalization condition.

Consequently, the ZFZS is expected to have a fine radial structure in addition to the well-known mesoscale structure (Diamond et al. Reference Diamond, Itoh, Itoh and Hahm2005), as a result of the RSAE fine radial mode structure highly localized around $q_{\min }$. For ZFZS dominated by $n=0, m=0$ scalar potential perturbation (Chen et al. Reference Chen, Lin and White2000), we take

(2.2)\begin{equation} \delta\phi_{Z} = A_{Z}\, \textrm{e}^{\textrm{i}\int\hat{k}_{Z}\, \textrm{d} r-\textrm{i}\omega_{Z}t}\sum_{j}\varPhi_{Z}(x-j)+\textrm{c.c.}, \end{equation}

with $\varPhi _{Z}$ accounting for the fine radial structure (Qiu et al. Reference Qiu, Chen and Zonca2016b) due to nonlinear mode coupling and $A_{Z}\exp {\textrm {i}\int \hat {k}_{Z}\, \textrm {d} r}$ being the well-known mesoscale structure. This general representation adopted here can be applied to recover the results obtained from the linear growth stage of the modulational instability, by separating the RSAE into pump and upper/lower sidebands, as often used in previous work (Chen et al. Reference Chen, Lin and White2000); and is also recovered in § 4, from the derived general nonlinear equations.

The governing equations describing the nonlinear processes can be derived from the quasi-neutrality condition

(2.3)\begin{equation} \frac{n_{0}\, \textrm{e}^{2}}{T_{i}}\left(1+\frac{T_{i}}{T_{e}}\right)\delta\phi_{k} = \sum_{s}\langle qJ_{k}\delta H_{k}\rangle_{s}\end{equation}

and the nonlinear gyrokinetic vorticity equation derived from parallel Ampère's law (Chen & Zonca Reference Chen and Zonca2016)

(2.4)\begin{align} & \frac{c^{2}}{4{\rm \pi}\omega_{k}^{2}}B\frac{\partial}{\partial l}\frac{k_{{\perp}}^{2}}{B}\frac{\partial}{\partial l}\delta\psi_k + \frac{\textrm{e}^{2}}{T_{i}}\langle (1-J_{k}^{2})F_{0}\rangle_{s} \delta\phi_{k}-\sum_{s}\left\langle \frac{q}{\omega_{k}}J_{k}\omega_{d}\delta H_{k}\right\rangle\nonumber\\ & \quad ={-}\textrm{i}\frac{c}{B_{0}\omega_{k}}\sum_{\boldsymbol{k}=\boldsymbol{k'} +\boldsymbol{k''}}\hat{\boldsymbol{b}}\cdot\boldsymbol{k''}\times \boldsymbol{k'}\left[\frac{c^{2}}{4{\rm \pi}}k_{{\perp}}''^{2} \frac{\partial_{l}\delta\psi_{k'}\partial_{l}\delta\psi_{k''}}{\omega_{k'} \omega_{k''}}\right.\nonumber\\ & \qquad +\left.\vphantom{\frac{c^{2}}{4{\rm \pi}}}\langle e(J_{k}J_{k'}-J_{k''}) \delta L_{k'}\delta H_{k''}\rangle \right]. \end{align}

Here, $J_{k}\equiv J_{0}(k_{\perp }\rho )$ with $J_{0}$ being the Bessel function of zero index accounting for finite Larmor radius effects, $\rho =v_{\perp }/\varOmega _{c}$ is the Larmor radius with $\varOmega _{c}$ being the cyclotron frequency, $F_{0}$ is the equilibrium particle distribution function, $\omega _{d}=(v_{\perp }^{2}+2v_{\parallel }^{2})(k_{r}\sin \theta +k_{\theta }\cos \theta )/(2\varOmega _{c}R)$ is the magnetic drift frequency, $l$ is the length along the equilibrium magnetic field line, $\langle \cdots \rangle$ means velocity space integration, $\sum _{s}$ is the summation of different particle species with $s=i, e$ representing ion and electron, and $\delta L_{k}\equiv \delta \phi _{k}-k_{\parallel }v_{\parallel }\delta \psi _{k}/\omega _{k}$. The three terms on the left-hand side of (2.4) are, respectively, the field line bending, inertial and curvature coupling terms, dominating the linear SAW physics. The two terms on the right-hand side of (2.4) correspond to Maxwell and Reynolds stresses (Chen et al. Reference Chen, Lin, White and Zonca2001) that contribute to nonlinear mode couplings as Maxwell and Reynolds stresses do not cancel each other, with their contribution dominating in the radially fast-varying inertial layer (Chen et al. Reference Chen, Lin and White2000), and $\sum _{\boldsymbol {k}=\boldsymbol {k'}+\boldsymbol {k''}}$ indicates the wavenumber and frequency matching condition required for nonlinear mode coupling. Here $\delta H_{k}$ is the non-adiabatic particle response, which can be derived from the nonlinear gyrokinetic equation (Frieman & Chen Reference Frieman and Chen1982):

(2.5)\begin{align} & (-\textrm{i}\omega_{k}+v_{{\parallel}}\partial_{l}+\textrm{i}\omega_{d})\delta H_{k} ={-}\textrm{i}\omega_{k}\frac{q}{T}F_{0}J_{k}\delta L_{k}\nonumber\\ & \quad -\frac{c}{B_{0}}\sum_{\boldsymbol{k}=\boldsymbol{k'} +\boldsymbol{k''}}\hat{\boldsymbol{b}}\cdot\boldsymbol{k''}\times \boldsymbol{k'}J_{k'}\delta L_{k'}\delta H_{k''}. \end{align}

For RSAE with $|k_{\parallel }v_{e}|\gg |\omega _k|\gg |k_{\parallel }v_{i}|, |\omega _{d}|$, the linear ion/electron responses can be derived to leading order as $\delta H^{L}_{k, i}=eF_{0}J_k\delta \phi _ k/T_{i}$ and $\delta H^{L}_{k,e}=-eF_{0}\delta \psi _{k}/T_{e}$. Furthermore, one can have that, to leading order, the ideal MHD constraint is satisfied, i.e. $\delta \phi _{R}=\delta \psi _{R}$, by substituting the ion/electron responses of the RSAE into the quasi-neutrality condition.

On the other hand, considering such a nonlinear system dominated by SAW instabilities, we can also use the parallel component of the nonlinear ideal Ohm's law as an alternative to (2.3):

(2.6)\begin{equation} \delta E_{{\parallel},k} ={-}\sum_{\boldsymbol{k}=\boldsymbol{k'}+ \boldsymbol{k''}}\hat{\boldsymbol{b}}\cdot\delta\boldsymbol{u}_{k'} \times\delta\boldsymbol{B}_{k''}/c,\end{equation}

with $\delta \boldsymbol {u}$ being the $\boldsymbol {E}\times \boldsymbol {B}$ drift velocity. We note that (2.6) is equivalent to (2.3), ignoring the high-order ${O}(k_{\perp }^{2}\rho _{i}^{2})$ corrections.

3. General nonlinear equations

In this section, the general nonlinear equations describing the self-consistent RSAE evolution are derived, including the generation of ZFZS and the feedback modulation of RSAE by ZFZS. Generally speaking, the nonlinear process can be divided into two stages, i.e. linear growth stage and strongly nonlinear stage, determined by whether the modulation to the pump wave is small. The governing equations derived in this section, without separating the RSAE into pump wave and its sidebands, are general, and can be used for describing both stages as shown in later sections (Guo, Chen & Zonca Reference Guo, Chen and Zonca2009; Chen et al. Reference Chen, Wei, Wei and Qiu2021).

Considering the nonlinear coupling dominated by the radially fast-varying inertial region, one can obtain the equation describing the electrostatic ZF excitation from the surface-averaged vorticity equation as

(3.1)\begin{equation} \omega_{Z}\hat{\chi}_{Z}\delta\phi_{Z} ={-}\textrm{i}\frac{c}{B}k_{\theta}\left(1-\frac{k_{{\parallel},0}^{2} v_{A}^{2}}{\omega_{0}^{2}}\right)(k_{r,0}-k_{r,0^{*}}) |\delta\phi_{0}|^{2}.\end{equation}

Here, $\hat {\chi }_{Z}=\chi _{Z}/(k_{Z}^{2}\rho _{i}^{2})\simeq 1.6q^{2}\epsilon ^{-1/2}$ with $\chi _{Z}$ being the well-known neoclassical shielding of ZFZS (Rosenbluth & Hinton Reference Rosenbluth and Hinton1998) and $\epsilon \equiv r/R$ being the inverse aspect ratio of the torus. One can note that $(k_{r,0}-k_{r,0^{*}})|\delta \varPhi _{0}|^{2}\equiv [(\hat {k}_{r,0}-\hat {k}_{r,0^{*}})-\textrm {i}(\partial _{r}\ln \varPhi _{0}- \partial _{r}\ln \varPhi _{0^{*}})]|\delta \varPhi _{0}|^{2}$ is radial modulation with $(\hat {k}_{r,0}-\hat {k}_{r,0^{*}})$ denoting envelope modulation (Chen & Zonca Reference Chen and Zonca2012) and $(\partial _{r}\ln \varPhi _{0}-\partial _{r}\ln \varPhi _{0^{*}})$ denoting parallel mode structure evolution (Qiu et al. Reference Qiu, Chen and Zonca2016b), which gives the fine radial structure of ZFZS. For RSAE typically dominated by one or two poloidal harmonics, $(\partial _{r}\ln \varPhi _{0}-\partial _{r}\ln \varPhi _{0^{*}})$ is the dominant term, and determines the zonal structure radial wavenumber $k_{Z}=-\textrm {i}(\partial _{r} \ln \varPhi _{0}-\partial _{r}\ln \varPhi _{0^{*}})$, as addressed in Qiu et al. (Reference Qiu, Chen and Zonca2017).

The equation describing the electromagnetic ZC excitation can be derived from (2.6), considering $k_{\parallel ,Z}=0$ and noting $\delta \psi _{Z}\equiv \omega _{0}\delta A_{\parallel ,Z}/(ck_{\parallel ,0})$ is defined using the frequency and parallel wavenumber of RSAE, as

(3.2)\begin{equation} \delta\psi_{Z} ={-}\textrm{i}\frac{c}{B}k_{\theta,0}k_{Z}\frac{1}{\omega_{0}} |\delta\phi_{0}|^{2}.\end{equation}

In deriving the (3.2), the ideal MHD condition for RSAE ($\delta \phi _{0}=\delta \psi _{0}$) is used, and $\partial _{r}\ln \delta \psi _{Z}=\partial _{r}\ln |\delta \phi _{0}|^{2}$ is noted.

One can also derive the corresponding equations describing RSAE from (2.6) as

(3.3)\begin{equation} \delta\phi_{0}-\delta\psi_{0} ={-}\textrm{i}\frac{c}{B}\frac{k_{Z} k_{\theta,0}}{\omega_{0}}\delta\phi_{0}(\delta\phi_{Z}- \delta\psi_{Z}),\end{equation}

which describes the deviation from the ideal MHD constraint due to nonlinear ZFZS modulation. The other equation for RSAE can be derived from the nonlinear vorticity equation as

(3.4)\begin{align} & k_{{\perp},0}^{2}\left(-\frac{k_{{\parallel},0}^{2}v_{A}^{2}}{\omega_{0}^{2}} \delta\psi_{0}+\delta\phi_{0}-\frac{\omega_{G}^{2}}{\omega_{0}^{2}} \delta\phi_{0}\right)\nonumber\\ & \quad ={-}\textrm{i}\frac{c}{B\omega_{0}}k_{Z}k_{\theta,0} (k_{Z}^{2}-k_{\theta,0}^{2})\delta\phi_{0} \left(\delta\phi_{Z}-\frac{k_{{\parallel},0}^{2}v_{A}^{2}}{\omega_{0}^{2}} \delta\psi_{Z}\right), \end{align}

with the term proportional to $\delta \phi _{Z}$ on the right-hand side corresponding to Reynolds stress contribution and the $\delta \psi _{Z}$ term corresponding to Maxwell contribution. The third term on the left-hand side of (3.4) is the SAW continuum upshift due to geodesic-curvature-induced compression, and $\omega _{G}$ is the frequency of geodesic acoustic mode (Qiu, Chen & Zonca Reference Qiu, Chen and Zonca2009). Note that (3.1)–(3.4) are the general equations for ZFZS generation by SAW instabilities in the Wentzel–Kramer–Brillouin (WKB) limit, and have expression similar to that describing ZFZS generation by TAE, as derived in Qiu et al. (Reference Qiu, Chen and Zonca2017), except the coefficient of the $\delta \psi$ term on the right-hand side of (3.4), where $k^2_{\parallel } v^2_{A}/\omega ^2\simeq 1$ is applied for TAE. However, the RSAE frequency is sensitively determined by $k_{\parallel }$ through $q_{\min }$, and is between the BAE and TAE frequency ranges, so a more general expression is derived here for ZFZS generation by RSAE. However, though with similar WKB expressions of dispersion relation, the physics underlying the ZFZS generation by RSAE is very different from that of the TAE case, as is embedded in the $k_{\parallel }$ term that determines the relative importance of various terms, for example, whether ZF or ZC generation should be dominated.

Substituting (3.3) into (3.4), one then obtains the equation describing the modulation of RSAE by ZFZS:

(3.5)\begin{equation} k_{{\perp},0}^{2}\mathscr{E}_{0}\delta\phi_{0} ={-}\textrm{i}\frac{c}{B\omega_{0}}\left(k_{Z}^{2}-k_{\theta,0}^{2}- \frac{k_{{\parallel},0}^{2}v_{A}^{2}}{\omega_{0}^{2}}k_{{\perp},0}^{2}\right) k_{Z}k_{\theta,0}\delta\phi_{0}(\delta\phi_{Z}-\alpha\delta\psi_{Z}),\end{equation}

with $\mathscr {E}_0$ being the RSAE dispersion relation and $\alpha \equiv (k_{\parallel ,0}^{2}v_{A}^{2}/\omega _{0}^{2})(-2k_{\theta , 0}^{2})/(k_{Z}^{2}-k_{\theta ,0}^{2}-k_{\parallel ,0}^{2}v_{A}^{2} k_{\perp ,0}^{2}/\omega _{0}^{2})$. Equation (3.5) is general, and can be reduced to various limits depending on different plasma parameters, through the value of $\alpha$ dependence on $k_{\parallel ,0}$; e.g. the mode dynamics described by (3.5) is similar to the TAE case with $(k_{\parallel ,0}^{2}v_{A}^{2}/\omega _{0}^{2})\sim {O}(1)$, and $|k_{\parallel ,0}|\simeq 1/(2qR)$, and thus $\alpha \simeq 1$. On the other hand, the mode behaviour gets close to a BAE with $k_{\parallel ,0}\simeq 0$, and thus $\alpha \simeq 0$. For simplicity of investigation, the RSAE WKB dispersion relation can be adopted here as $\mathscr {E}_{0}\simeq (1-k_{\parallel ,0}^{2}v_{A}^{2}/\omega _{0}^{2}- \omega _{G}^{2}/\omega _{0}^{2})$, while the radial global dispersion relation (Zonca et al. Reference Zonca, Briguglio, Chen, Dettrick, Fogaccia, Testa and Vlad2002) can be applied for more quantitative analysis.

Furthermore, subtracting (3.1) by $\alpha \times$ (3.2), one can obtain

(3.6)\begin{equation} \delta\phi_{Z}-\alpha\delta\psi_{Z} ={-}\textrm{i}\frac{c}{B}k_{Z}k_{\theta,0} \left[\frac{1-k_{{\parallel},0}^{2}v_{A}^{2}/\omega_{0}^{2}}{\omega_{Z} \hat{\chi}_{Z}k_{Z}}(k_{r,0}-k_{r,0^{*}})+\frac{\alpha}{\omega_{0}}\right] |\delta\phi_{0}|^{2},\end{equation}

which can be substituted into (3.5), and yield the general equation describing the self-modulation of RSAE as

(3.7)\begin{align} k_{{\perp},0}^{2}\mathscr{E}_{0}\delta\phi_{0} & ={-}\left(\frac{c}{B}k_{Z}k_{\theta,0}\right)^{2} \frac{1}{\omega_{0}}\left(k_{Z}^{2}-k_{\theta,0}^{2}- \frac{k_{\parallel0}^{2}v_{A}^{2}}{\omega_{0}^{2}}k_{\perp0}^{2}\right)\nonumber\\ & \quad \times \left[\frac{1-k_{{\parallel},0}^{2}v_{A}^{2}/\omega_{0}^{2}}{\omega_{Z} \hat{\chi}_{Z}k_{Z}}(k_{r,0}-k_{r,0^{*}})+ \frac{\alpha}{\omega_{0}}\right]\delta\phi_{0}|\delta\phi_{0}|^{2}. \end{align}

Both ZF and ZC generation by RSAE are systematically accounted for in (3.7) on the same footing, with the first term in square brackets corresponding to ZF generation and the second term to ZC. On the one hand, which one is preferentially excited is addressed in § 4. On the other hand, ZFZS generation can lead to RSAE saturation by scattering it to linearly stable radial eigenstates. The nonlinear saturation level can be determined by self-consistently solving (3.7) as a nonlinear Schrödinger equation (Chen et al. Reference Chen, Wei, Wei and Qiu2021), while a rough estimation is given in, for example, Qiu et al. (Reference Qiu, Chen, Zonca and Chen2018a), by separating the RSAE into a pump and its sidebands, and deriving the fixed-point solution of the coupled nonlinear equations. Since RSAE linear properties are very sensitive to the $q$-profile, the modulation of the$q$-profile caused by the nonlinearly generated ZC may have a great impact on RSAE nonlinear saturation. This is discussed in § 5.

4. Spontaneous excitation of ZFZS by RSAE via modulational instability

To investigate the linear growth stage of the modulational instability, we follow the analysis of Chen & Zonca (Reference Chen and Zonca2012), and consider the fluctuation consisting of a constant-amplitude pump wave $\varOmega _{P}\equiv \varOmega _{P}(\omega _{P}, \boldsymbol {k}_{P})$ and its upper and lower sidebands $\varOmega _{\pm }\equiv \varOmega _{\pm }(\omega _{\pm }, \boldsymbol {k}_{\pm })$ due to the modulation of the ZFZS $\varOmega _{Z}\equiv \varOmega _{Z}(\omega _{Z}, \boldsymbol {k}_{Z})$ (Chen et al. Reference Chen, Lin and White2000). Here, subscripts ‘$P$’, ‘$+$’ and ‘$-$’ denote RSAE pump, upper sideband and lower sideband, respectively, with $\delta \phi _{0}=\delta \phi _{P}+\delta \phi _{+}$, $\delta \phi _{0^{*}}=\delta \phi _{P^{*}}+\delta \phi _{-}$, and

(4.1)\begin{gather} \delta\phi_{P} = A_{P}\, \textrm{e}^{\textrm{i}\left(n\phi-m_{0}\theta-\omega_{P}t\right)}\sum_{j}\, \textrm{e}^{-\textrm{i}j\theta}\varPhi_{P}\left(x-j\right)+\textrm{c.c.}, \end{gather}
(4.2)\begin{gather}\delta\phi_{{\pm}} = A_{{\pm}}\, \textrm{e}^{{\pm} \textrm{i}\left(n\phi-m_{0}\theta-\omega_{P}t\right)}\, \textrm{e}^{\textrm{i}\left(\int\widehat{k_{Z}}\, \textrm{d} r-\omega_{Z}t\right)} \sum_{j}\, \textrm{e}^{{\mp} ij\theta}\left\{ \begin{array}{c} \varPhi_{P}\left(x-j\right)\\ \varPhi_{P^{*}}\left(x-j\right) \end{array}\right\} +\textrm{c.c.} \end{gather}

Then the general nonlinear equations (3.1)–(3.4) can be reduced to equations describing $\delta \phi _{Z}$, $\delta \phi _{+}$ and $\delta \phi _{-}$ generation by the fixed-amplitude pump RSAE, while the feedback of ZFZS and RSAE sidebands to the pump wave is neglected, focusing on the initial stage of the nonlinear process. Considering the frequency/wavenumber matching condition ($\omega _{\pm }=\pm \omega _{P}+\omega _{Z}$, $\boldsymbol {k}_{\pm }=\pm \boldsymbol {k}_{P}+\boldsymbol {k}_{Z}$) embedded in the above expressions, equation (3.1) can be reduced to

(4.3)\begin{equation} \omega_{Z}\hat{\chi}_{Z}\delta\phi_{Z} ={-}\textrm{i}\frac{c}{B}k_{Z}k_{\theta,P}\left(1-\frac{k_{{\parallel},P}^{2} v_{A}^{2}}{\omega_{P}^{2}}\right) (\delta\phi_{+}\delta\phi_{P^{*}}-\delta\phi_{-} \delta\phi_{P}),\end{equation}

with $(1-k^{2}_{\parallel ,P}v^{2}_{A}/\omega ^{2}_{P})$ representing the competition of Reynolds and Maxwell stresses in breaking the pure Alfvénic state (Chen & Zonca Reference Chen and Zonca2012Reference Chen and Zonca2013). On the other hand, (3.2) describing ZC excitation can be reduced to

(4.4)\begin{equation} \delta\psi_{Z} ={-}\textrm{i}\frac{c}{B}k_{\theta,P}k_{Z} \frac{1}{\omega_{P}}(\delta\phi_{+}\delta\phi_{P^{*}}+ \delta\phi_{-}\delta\phi_{P}).\end{equation}

The nonlinear equation describing RSAE sideband generation through the ZFZS modulation to pump RSAE can be derived from (3.5) as

(4.5)\begin{align} k_{{\perp},\pm}^{2}\mathscr{E}_{{\pm}}\delta\phi_{{\pm}} & ={-}\textrm{i}\frac{c}{B\omega_{{\pm}}}\left(k_{Z}^{2}-k_{\theta,P}^{2}- \frac{k_{{\parallel},P}^{2}v_{A}^{2}}{\omega_{P}^{2}}k_{{\perp},\pm}^{2}\right)\nonumber\\ & \quad \times k_{Z}k_{\theta,P}\left\{ \begin{array}{c} \delta\phi_{P}\\ \delta\phi_{P^{*}} \end{array}\right\} (\delta\phi_{Z}-\alpha\delta\psi_{Z}). \end{align}

Equations (4.3)–(4.5) are equivalent to (34)–(36) for TAE cases as derived in Qiu et al. (Reference Qiu, Chen and Zonca2017), with the coefficient $\alpha$ generalized to include a broader parameter regime ($\alpha \simeq 1$ for TAE as discussed in Qiu et al. (Reference Qiu, Chen and Zonca2017)). Note that $k_{\perp ,\pm }^{2}=k_{\perp ,P}^{2}+k_{Z}^{2}$ and $k_{\perp ,+}^{2}$ are used in the derivation later. Similarly, subtracting (4.3) by $\alpha \times$ (4.4), one can obtain

(4.6)\begin{align} \delta\phi_{Z}-\alpha\delta\psi_{Z} & = \textrm{i}\frac{c}{B}k_{Z}k_{\theta,P} \left[\left(\frac{1-k_{{\parallel},P}^{2}v_{A}^{2}/\omega_{P}^{2}}{\omega_{Z} \hat{\chi}_{Z}}+\frac{\alpha}{\omega_{P}}\right)\delta\phi_{+} \delta\phi_{P^{*}}\right.\nonumber\\ & \quad \left.-\left(\frac{1-k_{{\parallel},P}^{2}v_{A}^{2}/\omega_{P}^{2}}{\omega_{Z} \hat{\chi}_{Z}}-\frac{\alpha}{\omega_{P}}\right)\delta\phi_{-}\delta\phi_{P}\right]. \end{align}

The modulational instability dispersion relation can then be derived by substituting (4.5) into (4.6) as

(4.7)\begin{align} 1 & ={-}\hat{F}\left|\delta\phi_{P}\right|^{2}\left[\left(\frac{1-k_{{\parallel},P}^{2} v_{A}^{2}/\omega_{P}^{2}}{\omega_{Z}\hat{\chi}_{Z}}+ \frac{\alpha}{\omega_{P}}\right)\frac{1}{\mathscr{E}_{+}}\right.\nonumber\\ & \quad -\left.\left(\frac{1-k_{{\parallel},P}^{2}v_{A}^{2}/\omega_{P}^{2}}{\omega_{Z} \hat{\chi}_{Z}}-\frac{\alpha}{\omega_{P}}\right) \frac{1}{\mathscr{E}_{-}}\right], \end{align}

with $\hat {F}=(ck_{Z}k_{\theta ,P}/B)^{2}(-k_{Z}^{2}+k_{\theta ,P}^{2} +k_{\parallel ,P}^{2}v_{A}^{2}k_{\perp ,+}^{2}/\omega _{P}^{2})/(\omega _{P}k_{\perp ,+}^{2})$ being a nonlinear coupling coefficient. Furthermore, considering that RSAE sidebands still obey the dispersion relation of RSAE by $\mathscr {E}_{\pm }=\mathscr {E}_{0}(\omega _Z\pm \omega _P, k_{Z})$, one can expand $\mathscr {E}_{\pm }$ along the RSAE characteristics, as $\mathscr {E}_{\pm }\simeq (\partial \mathscr {E}_{0}/\partial \omega _{0})(\pm \omega _{Z}-\varDelta )$ with $\varDelta \equiv -k_{Z}^{2}(\partial ^{2}\mathscr {E}_{0}/\partial k_{r}^{2})/(2\partial \mathscr {E}_{0}/\partial \omega _{0})$ being the frequency mismatch, describing the frequency shift of RSAE sidebands from the pump RSAE dispersion relation due to the ZFZS modulation. Denoting $\gamma \equiv -\textrm {i}\omega _{Z}$ and noting $\omega _{\pm }\simeq \pm \omega _{P}$, the modulational instability dispersion relation can be written as

(4.8)\begin{equation} \gamma^{2} ={-}\varDelta^{2}+\frac{2\hat{F} |\delta\phi_{P}|^{2}}{\partial\mathscr{E}_{0}/\partial\omega_{0}} \left(\frac{1-k_{{\parallel},P}^{2}v_{A}^{2}/\omega_{0}^{2}}{\hat{\chi}_{Z}} +\frac{\alpha}{\omega_{P}}\varDelta\right).\end{equation}

The first term on the right-hand side of (4.8) is the threshold condition due to frequency mismatch and the second term represents the nonlinear drive. Thus, the ZFZS can be spontaneously excited when the nonlinear drive overcomes the threshold condition due to frequency mismatch, as the RSAE amplitude is large enough, or the nonlinear coupling is strong enough, as we address in the following discussion. Furthermore, the first term in parentheses corresponds to the ZF contribution to the nonlinear coupling, and the second term corresponds to ZC. For the ZF contribution, there are two restrictions due to, first, the partial cancellation of Reynolds and Maxwell stresses with the ‘residual’ drive due to deviation from the ideal MHD limit due to plasma non-uniformity (reversed $q$-profile here) that breaks the pure Alfvénic state (Zonca et al. Reference Zonca, Briguglio, Chen, Dettrick, Fogaccia, Testa and Vlad2002; Chen & Zonca Reference Chen and Zonca2013), and second, the neoclassical shielding of ZF as shown by $\hat {\chi }_{Z}$ in the denominator, with $\hat {\chi }_{Z}\sim q^{2}/\epsilon$, which is typically much larger than unity (Rosenbluth & Hinton Reference Rosenbluth and Hinton1998; Chen & Zonca Reference Chen and Zonca2016).

For the ZC contribution, there are also two important factors that crucially determine the nonlinear process, with the first being the sign of $\varDelta$, which is typically determined by specific plasma parameters. The ZC term is a driving term for $\varDelta >0$; while for $\varDelta <0$, the ZC term becomes a damping term for this nonlinear process; and then the condition for modulational instability becomes very stringent, with additional requirement for the ZF term being dominant over the ZC term, which is not easy to satisfy due to the two restrictions as addressed in the paragraph above. The other important factor is the value of $\alpha$. As noted before, if RSAE localizes near the rational surface, $\alpha \simeq 0$ because of $k_{\parallel }\simeq 0$, meaning that ZC generation is very weak and is similar to the BAE case investigated in Qiu et al. (Reference Qiu, Chen and Zonca2016b); on the other hand, if RSAE localizes in the middle of two neighbouring rational surfaces, $\alpha \simeq 1$, and this case is similar to the TAE case (Chen & Zonca Reference Chen and Zonca2012) with ZC generation preferred. So for RSAE, with $k_{\parallel }$ and its frequency determined by $q_{\min }$ and the corresponding mode numbers, both ZF and ZC generation could be dominant, depending on the specific plasma parameters, and should be investigated case by case. Furthermore, the threshold amplitude can be roughly estimated in two limit cases, e.g. as RSAE frequency approaches TAE and BAE frequencies, as $\delta B_{\theta }/B \sim {O}(10^{-4})$ (Chen & Zonca Reference Chen and Zonca2012; Qiu et al. Reference Qiu, Chen and Zonca2016b).

5. Nonlinear RSAE saturation

In strongly nonlinear stage, the feedback of ZFZS and RSAE sidebands to the pump wave can no longer be neglected, as the sideband amplitudes become comparable to that of the pump wave. It is indicated in (3.7) that ZS can play self-regulatory roles in RSAE nonlinear evolution by scattering the RSAE into short-radial-wavelength stable domains, which may lead to RSAE saturation. The saturation level can be derived from the coupled pump wave and sideband equations, as is shown in, for example, Zonca & Chen (Reference Zonca and Chen2008). In addition, another related channel unique for RSAE nonlinear saturation may exist, due to the modulation to the SAW continuum (Zonca et al. Reference Zonca, Romanelli, Vlad and Kar1995; Chen et al. Reference Chen, Zonca, Santoro and Hu1998) by the nonlinearly generated ZS (among which ZC plays a dominant role), considering the sensitive dependence of RSAE on SAW continuum accumulation point (for a visualization of RSAE physics dependence on $q_{\min }$, interested readers may refer to Wang et al. (Reference Wang, Qiu, Zonca, Briguglio and Vlad2020) and figure 3 therein). The nonlinearly generated ZC is a toroidal current sharply localized around $q_{\min }$, which can generate a perturbed poloidal magnetic field and further modulate the $q$-profile and thus the SAW continuum near $q_{\min }$. Thus, one can reasonably speculate that the ZC plays an important role in RSAE saturation by modifying the equilibrium continuum, similar to the mechanism investigated in Zonca et al. (Reference Zonca, Romanelli, Vlad and Kar1995) and Chen et al. (Reference Chen, Zonca, Santoro and Hu1998) for TAE.

Here, consistent with the above speculation on the crucial role played by the ZC, we consider a simplified case that ZC generation is dominant. This assumption is natural for scenarios with $(k_{\parallel ,0}^{2}v_{A}^{2}/\omega _{0}^{2})\sim {O}(1)$; however, it may also be important for other parameter regimes for the reasons addressed above. Thus, (3.7) can be simplified as

(5.1)\begin{equation} \mathscr{E}_{0}\delta\phi_{0} = 2\left(\frac{c}{B\omega_{0}}k_{Z}k_{\theta,0}\right)^{2}\delta\phi_{0} |\delta\phi_{0}|^{2}.\end{equation}

Taking a two-scale analysis by assuming $\omega _{R}=\omega _{0}+\textrm {i}\partial _{\tau }$, and expanding $\mathscr {E}_{0}\simeq (\partial \mathscr {E}_{0}/\partial \omega _{0})(\textrm {i}\partial _{\tau }-\textrm {i}\gamma ^{L}_{R}-\varDelta )$ with $\varDelta$ being the nonlinearity-induced frequency shift and $\gamma ^{L}_{R}$ the linear RSAE growth rate,Footnote 1 (5.1) becomes

(5.2)\begin{equation} \left[\textrm{i}\partial_{\tau}-\textrm{i}\gamma^{L}_{R}-\varDelta-2\left(\frac{c}{B\omega_{0}}k_{Z}k_{\theta,0}\right)^{2} \frac{|\delta\phi_{0}|^{2}}{\partial\mathscr{E}_{0}/\partial\omega_{0}}\right]\delta\phi_{0} = 0.\end{equation}

Equation (5.2) describes the RSAE nonlinear evolution due to scattering to different radial eigenstates (denoted by $\varDelta$) with different linear growth/damping rates ($\gamma ^{L}_{R}$) and nonlinear self-modulation by ZC generation, and the saturation level can be estimated by balancing the frequency shift (Max($|\gamma ^{L}_{R}|$, $|\varDelta |$)) and the nonlinear RSAE modulation by the ZC. Then one has

(5.3)\begin{equation} |\delta\phi_{0}|^{2} = \frac{\partial^{2}\mathscr{E}_{0}}{\partial k_{r}^{2}} \left(\frac{B\omega_{0}}{2ck_{\theta,0}}\right)^{2}.\end{equation}

Equation (5.3) describes the RSAE saturation level due to scattering by self-generated ZC to neighbouring (linearly stabler) radial eigenstates, assuming $\varDelta \gg \gamma ^{L}_{R}$. Cases with $\varDelta \ll \gamma ^{L}_{R}$ can be evaluated similarly. The RSAE saturation level can be estimated by substituting typical parameters into the expression. Furthermore, (5.3) can be substituted into (3.2), and the saturation level of the perturbed poloidal magnetic field $\delta B_{\theta }$ can be estimated as

(5.4)\begin{equation} \delta B_{\theta} \sim \frac{B_{0}k_{{\parallel},0}k_{Z}^{2}}{4k_{\theta,0}} \left.\frac{\partial^{2}\mathscr{E}_{0}}{\partial k_{r}^{2}}\right|_{k_{r}=0},\end{equation}

resulting in a modulation of local $q_{\min }$ by

(5.5)\begin{equation} \delta q \sim{-}q_{\min}\frac{B_{0}k_{{\parallel},0}k_{Z}^{2}}{4B_{\theta}k_{\theta,0}} \left.\frac{\partial^{2}\mathscr{E}_{0}}{\partial k_{r}^{2}}\right|_{k_{r}=0}.\end{equation}

In deriving (5.4) and (5.5), we have noted $\delta \psi =\omega \delta A_{\parallel }/(ck_{\parallel })$ and $\boldsymbol {\delta B}=\nabla \times \delta A_{\parallel }\boldsymbol {b}$. Typical parameters can be adopted, i.e. $q_{\min }\sim {O}(1)$, $B_{0}/B_{\theta }\sim qR/r_{0}$, $k_{\parallel }\sim 1/(qR)$, $k_{\theta ,0}\rho _{d}\sim {O}(1)$ with $\rho _{d}$ being the EP drift orbit radius and

(5.6)\begin{equation} k_{Z}^{2}\left.\frac{\partial^{2}\mathscr{E}_{0}}{\partial k_{r}^{2}}\right|_{k_{r}=0} \sim \frac{4\varDelta}{\omega},\end{equation}

which can be reasonably assumed as $\sim {O}(0.1)$. Thus, one can roughly estimate that $\delta B_{\theta }/B \sim {O}(10^{-4})$ as saturation amplitude and $\delta q/q\sim {O}(10^{-3})$. Such RSAE nonlinear saturation amplitude is equivalent to the estimation from the fixed-point solution in the driven-dissipative system described by three coupled equations such as (45)–(47) in Qiu et al. (Reference Qiu, Chen and Zonca2019a), and is in fact the same as the threshold amplitude on ZFZS nonlinear excitation. However, we note this is a rough order-of-magnitude estimation, since the nonlinear driven-dissipative system does not necessarily show a stationary saturation as described by the fixed-point solution. In fact, depending on the parameter regimes such as driving/dissipative rate and the initial conditions, the system may exhibit limit cycle oscillation, period doubling as well as route to chaos (Russell, Hanson & Ott Reference Russell, Hanson and Ott1980). Noting that the modification to local RSAE continuum frequency is $\sim O(n\delta qv_{A}/(qR))$ and that for reactor burning plasma with $\rho _{d}/a\sim O(10^{-2})$ most unstable RSAEs are characterized by $n\gtrsim O(10)$ (Wang et al. Reference Wang, Qiu, Zonca, Briguglio, Fogaccia, Vlad and Wang2018), the modification to local SAW continuum is comparable to the RSAE linear growth rate $\gamma ^{L}_{R}$ or frequency differences between different radial eigenstates ($\sim \varDelta$). Thus, one expects the ZC-induced SAW continuum modification in the vicinity of $q_{\min }$ to play an important role in RSAE nonlinear saturation, though the self-consistent study analogous to Zonca et al. (Reference Zonca, Romanelli, Vlad and Kar1995) and Chen et al. (Reference Chen, Zonca, Santoro and Hu1998) is not presented. The systematic investigation of RSAE saturation due to nonlinear modification of SAW continuum and the resulting enhanced continuum damping will be presented in a separate publication.

6. Conclusion and discussion

The general equations describing RSAE self-modulation via nonlinear excitation of ZFZS are derived using gyrokinetic theory, which is then applied to study the spontaneous ZFZS excitation via modulational instability as well as RSAE nonlinear saturation due to scattering to stabler radial eigenstates. It is found that both ZF and ZC can be dominant in the spontaneous excitation by RSAE, depending on the specific plasma parameters, especially $q_{\min }$ that determines the RSAE parallel wavenumber and frequency. The obtained general modulational instability dispersion relation for ZFZS excitation by RSAE, (4.8), can recover the results of TAE (Chen & Zonca Reference Chen and Zonca2012) and BAE (Qiu et al. Reference Qiu, Chen and Zonca2016b) in the proper limits, i.e. by taking $|k_{\parallel }v_{A}/\omega |\rightarrow 1$ and $0$, respectively. The properties of ZFZS generation by RSAE, noting that the typical RSAE parallel wavenumber and frequency are between those of TAE and BAE, can be understood based on the knowledge obtained from TAE (Chen & Zonca Reference Chen and Zonca2012) and BAE (Qiu et al. Reference Qiu, Chen and Zonca2016b).

An interesting step forward is that the saturation level of RSAE is qualitatively estimated by balancing the nonlinear scattering by ZFZS with the frequency differences between different radial eigenstates ($\sim \varDelta$), assuming ZC playing a dominant role in RSAE scattering. The corresponding ZC saturation level as well as the modification to local $q_{\min }$ are also estimated. It is found that the resulting modification to local SAW continuum accumulation point frequency can be at least comparable to the RSAE linear growth rate or frequency mismatch between different radial eigenstates for burning plasma scenarios with most unstable RSAEs characterized by $n\gtrsim O(10)$ (Wang et al. Reference Wang, Qiu, Zonca, Briguglio, Fogaccia, Vlad and Wang2018). Thus, the modification of local SAW continuum by ZC is expected to contribute significantly to RSAE saturation (Zonca et al. Reference Zonca, Romanelli, Vlad and Kar1995; Chen et al. Reference Chen, Zonca, Santoro and Hu1998). And it is natural to speculate that similar physical processes may happen in the regions sensitive to the magnetic field perturbation. For example, in the region near the X-point, one expects that ZC may also be driven by edge MHD modes such as the kinetic ballooning mode, and this may be important for the equilibrium and stability of a tokamak, and lead to, for example, vertical instability.

The above estimation based on (5.1), assuming dominant ZC generation by taking $|k_{\parallel }v_{A}/\omega |\sim 1$, is valid for other parameter regimes due to the weak coupling coefficients of ZF generation, except for the cases where $q_{\min }$ is localized very close to a low-order rational surface, such that the RSAE properties are close to those of BAE with predominantly ZF generation (Qiu et al. Reference Qiu, Chen and Zonca2016b). The logic underlying the reasoning presented in § 5 is that the RSAE and ZFZS saturation levels are estimated without accounting for the modification to the SAW continuum, which is then used to estimate the modification to the SAW continuum by the saturated ZC, and it is found that the modification to the SAW continuum could be comparable to or even more important than the ZFZS shearing. Thus, the obtained results indicate that the modification to the SAW continuum will start to influence the RSAE nonlinear evolution, before it saturates due to self-modulation via ZFZS generation. Our work thus indicates that multiple processes may contribute comparably to the RSAE saturation, and should be accounted for on the same footing, based on the solid understanding of each individual process, to properly assess the saturation and thus EP transport by RSAE. This is of particular importance since RSAEs are expected to be strongly excited by core-localized fusion alphas in future reactors characterized by advanced reversed shear scenarios.

Acknowledgements

The authors acknowledge Professor L. Chen (Zhejiang University, China and University of California, Irvine) and Dr F. Zonca (ENEA, Italy) for fruitful discussions.

Editor Peter Catto thanks the referees for their advice in evaluating this article.

Funding

This work is supported by the National Key R&D Program of China (Z.Q., grant no. 2017YFE0301900) and the National Science Foundation of China (Z.Q., grant no. 11875233). Z.Q. is also supported by "Users of Excellence program of Hefei Science Center CAS unser Contract No. 2021HSC-UE016".

Declaration of interest

The authors report no conflict of interest.

Data availability

The data that support the findings of this study are available from the corresponding author upon reasonable request.

Footnotes

1 Note the linear RSAE growth/damping rate here, which is not included in (4.8) assuming RSAE sideband damping rates are typically smaller than frequency mismatch.

References

REFERENCES

Berk, H.L. & Breizman, B.N. 1990 Saturation of a single mode driven by an energetic injected beam. III. Alfvén wave problem. Phys. Fluids B 2 (9), 2246.CrossRefGoogle Scholar
Biancalani, A., Bottino, A., Lauber, P., Mishchenko, A. & Vannini, F. 2020 Effect of the electron redistribution on the nonlinear saturation of Alfvén eigenmodes and the excitation of zonal flows. J. Plasma Phys. 86 (3), 825860301.CrossRefGoogle Scholar
Cheng, C., Chen, L. & Chance, M. 1985 High-n ideal and resistive shear Alfvén waves in tokamaks. Ann. Phys. 161, 21.CrossRefGoogle Scholar
Chen, L. 1999 Theory of plasma transport induced by low-frequency hydromagnetic waves. J. Geophys. Res.: Space Phys. 104 (A2), 2421.CrossRefGoogle Scholar
Chen, L., Lin, Z. & White, R. 2000 Excitation of zonal flow by drift waves in toroidal plasmas. Phys. Plasmas 7 (8), 31293132.CrossRefGoogle Scholar
Chen, L., Lin, Z., White, R.B. & Zonca, F. 2001 Non-linear zonal dynamics of drift and drift-Alfvén turbulence in tokamak plasmas. Nucl. Fusion 41 (6), 747.CrossRefGoogle Scholar
Chen, L. & Zonca, F. 2012 Nonlinear excitations of zonal structures by toroidal Alfvén eigenmodes. Phys. Rev. Lett. 109, 145002.CrossRefGoogle ScholarPubMed
Chen, L. & Zonca, F. 2013 On nonlinear physics of shear Alfvén waves. Phys. Plasmas 20 (5).CrossRefGoogle Scholar
Chen, L. & Zonca, F. 2016 Alfvén waves and energetic particles. Rev. Mod. Phys. 88 (1), 015008.CrossRefGoogle Scholar
Chen, L., Zonca, F., Santoro, R. & Hu, G. 1998 Nonlinear dynamics of Alfvén eigenmodes in toroidal plasmas. Plasma Phys. Control. Fusion 40 (11), 1823.CrossRefGoogle Scholar
Chen, N., Wei, S., Wei, G. & Qiu, Z. 2021 Soliton generation and drift wave turbulence spreading via geodesic acoustic mode excitation. Plasma Phys. Control. Fusion (submitted).Google Scholar
Chen, W., et al. 2014 Destabilization of reversed shear Alfvén eigenmodes driven by energetic ions during NBI in hl-2a plasmas with $q_{\min } \sim 1$. Nucl. Fusion 54 (10), 104002.CrossRefGoogle Scholar
Connor, J., Hastie, R. & Taylor, J. 1978 Shear, periodicity, and plasma ballooning modes. Phys. Rev. Lett. 40 (6), 396.CrossRefGoogle Scholar
Diamond, P.H., Itoh, S.-I., Itoh, K. & Hahm, T.S. 2005 Zonal flows in plasma: a review. Plasma Phys. Control. Fusion 47 (5), R35.CrossRefGoogle Scholar
Ding, R., Pitts, R., Borodin, D., Carpentier, S., Ding, F., Gong, X., Guo, H., Kirschner, A., Kocan, M., Li, J., Luo, G.-N., Mao, H., Qian, J., Stangeby, P., Wampler, W., Wang, H. & Wang, W. 2015 Material migration studies with an iter first wall panel proxy on east. Nucl. Fusion 55 (2), 023013.CrossRefGoogle Scholar
Fasoli, A., Gormenzano, C., Berk, H., Breizman, B., Briguglio, S., Darrow, D., Gorelenkov, N., Heidbrink, W., Jaun, A., Konovalov, S., Nazikian, R., Noterdaeme, J.-M., Sharapov, S., Shinohara, K., Testa, D., Tobita, K., Todo, Y., Vlad, G. & Zonca, F. 2007 Chapter 5: physics of energetic ions. Nucl. Fusion 47 (6), S264.CrossRefGoogle Scholar
Fasoli, A., Testa, D., Sharapov, S., Berk, H.L., Breizman, B., Gondhalekar, A., Heeter, R.F., Mantsinen, M. & contributors to the EFDA-JET Workprogramme 2002 MHD spectroscopy. Plasma Phys. Control. Fusion 44 (12B), B159B172.CrossRefGoogle Scholar
Frieman, E.A. & Chen, L. 1982 Nonlinear gyrokinetic equations for low-frequency electromagnetic waves in general plasma equilibria. Phys. Fluids 25 (3), 502508.CrossRefGoogle Scholar
Gormezano, C., et al. 2007 Chapter 6: steady state operation. Nucl. Fusion 47, S285S336.CrossRefGoogle Scholar
Guo, Z., Chen, L. & Zonca, F. 2009 Radial spreading of drift-wave & zonal-flow turbulence via soliton formation. Phys. Rev. Lett. 103, 055002.CrossRefGoogle ScholarPubMed
Hahm, T.S., Beer, M.A., Lin, Z., Hammett, G.W., Lee, W.W. & Tang, W.M. 1999 Shearing rate of time-dependent $e \times b$ flow. Phys. Plasmas 6 (3), 922.CrossRefGoogle Scholar
Hahm, T.S. & Chen, L. 1995 Nonlinear saturation of toroidal Alfvén eigenmodes via ion compton scattering. Phys. Rev. Lett. 74, 266.CrossRefGoogle ScholarPubMed
Huang, J., et al. 2020 Progress in extending high poloidal beta scenarios on diii-d towards a steady-state fusion reactor and impact of energetic particles. Nucl. Fusion 60 (12), 126007.CrossRefGoogle Scholar
Lauber, P. 2013 Super-thermal particles in hot plasmas-kinetic models, numerical solution strategies, and comparison to tokamak experiments. Phys. Rep. 533 (2), 3368.CrossRefGoogle Scholar
Lin, Z., Hahm, T.S., Lee, W.W., Tang, W.M. & White, R.B. 1998 Turbulent transport reduction by zonal flows: Massively parallel simulations. Science 281 (5384), 18351837.CrossRefGoogle ScholarPubMed
Qiu, Z., Chen, L. & Zonca, F. 2009 Collisionless damping of short wavelength geodesic acoustic modes. Plasma Phys. Control. Fusion 51 (1), 012001.CrossRefGoogle Scholar
Qiu, Z., Chen, L. & Zonca, F. 2016 a Effects of energetic particles on zonal flow generation by toroidal Alfvén eigenmode. Phys. Plasmas 23 (9), 090702.CrossRefGoogle Scholar
Qiu, Z., Chen, L. & Zonca, F. 2016 b Fine radial structure zonal flow excitation by beta-induced Alfvén eigenmode. Nucl. Fusion 56 (10), 106013.CrossRefGoogle Scholar
Qiu, Z., Chen, L. & Zonca, F. 2017 Nonlinear excitation of finite-radial-scale zonal structures by toroidal Alfvén eigenmode. Nucl. Fusion 57 (05), 056017.CrossRefGoogle Scholar
Qiu, Z., Chen, L. & Zonca, F. 2019 a Gyrokinetic theory of the nonlinear saturation of a toroidal Alfvén eigenmode. Nucl. Fusion 59 (6), 066024.CrossRefGoogle Scholar
Qiu, Z., Chen, L., Zonca, F. & Chen, W. 2018 a Nonlinear decay and plasma heating by a toroidal Alfvén eigenmode. Phys. Rev. Lett. 120 (13), 135001.CrossRefGoogle ScholarPubMed
Qiu, Z., Chen, L., Zonca, F. & Chen, W. 2018 b Nonlinear decay and plasma heating by toroidal Alfvén eigenmodes. In Proceedings of the 27th Fusion Energy Conference, Gandhinagar, India, pp. 22–27.Google Scholar
Qiu, Z., Chen, L., Zonca, F. & Chen, W. 2019 b Nonlinear excitation of a geodesic acoustic mode by toroidal Alfvén eigenmodes and the impact on plasma performance. Nucl. Fusion 59 (6), 066031.CrossRefGoogle Scholar
Rosenbluth, M.N. & Hinton, F.L. 1998 Poloidal flow driven by ion-temperature-gradient turbulence in tokamaks. Phys. Rev. Lett. 80, 724727.CrossRefGoogle Scholar
Russell, D.A., Hanson, J.D. & Ott, E. 1980 Dimension of strange attractors. Phys. Rev. Lett. 45, 11751178.CrossRefGoogle Scholar
Sharapov, S.E., Alper, B., Berk, H.L., Borba, D.N., Breizman, B.N., Challis, C.D., Fasoli, A., Hawkes, N.C., Hender, T.C., Mailloux, J., Pinches, S.D. & Testa, D., 2002 Alfvén wave cascades in a tokamak. Phys. Plasmas 9, 2027.CrossRefGoogle Scholar
Sharapov, S.E., Testa, D., Alper, B., Borba, D.N., Fasoli, A., Hawkes, N.C., Heeter, R.F., Mantsinen, M.J. & Hellermann, M.G.V. 2001 Mhd spectroscopy through detecting toroidal Alfvén eigenmodes and Alfvén wave cascades. Phys. Lett. A 289, 127.CrossRefGoogle Scholar
Shi, P., Qiu, Z., Chen, W., Wang, Z., Shi, Z., Yu, L., Yang, Z., Zhong, W., Jiang, M., Ji, X., Yang, Q., Xu, M. & Duan, X. 2020 Thermal ions heat transport induced by reversed shear Alfvén eigenmode on the hl-2a tokamak. Nucl. Fusion 60, 064001.CrossRefGoogle Scholar
Todo, Y., Berk, H. & Breizman, B. 2010 Nonlinear magnetohydrodynamic effects on Alfvén eigenmode evolution and zonal flow generation. Nucl. Fusion 50 (8), 084016.CrossRefGoogle Scholar
Tomabechi, K., Gilleland, J., Sokolov, Y., Toschi, R. & the ITER Team 1991 Iter conceptual design. Nucl. Fusion 31 (6), 1135.CrossRefGoogle Scholar
Wang, T., Qiu, Z., Zonca, F., Briguglio, S., Fogaccia, G., Vlad, G. & Wang, X. 2018 Shear Alfvén fluctuation spectrum in divertor tokamak test facility plasmas. Phys. Plasmas 25 (6), 062509.CrossRefGoogle Scholar
Wang, T., Qiu, Z., Zonca, F., Briguglio, S. & Vlad, G. 2020 Dynamics of reversed shear Alfvén eigenmode and energetic particles during current ramp-up. Nucl. Fusion 60 (12), 126032.CrossRefGoogle Scholar
Wang, T., Wang, X., Briguglio, S., Qiu, Z., Vlad, G. & Zonca, F. 2019 Nonlinear dynamics of shear Alfvén fluctuations in divertor tokamak test facility plasmas. Phys. Plasmas 26 (1), 012504.CrossRefGoogle Scholar
Wei, S., Wang, Y., Shi, P., Chen, W., Chen, N. & Qiu, Z. 2021 Nonlinear coupling of reversed shear Alfvén eigenmode and toroidal Alfvén eigenmode during current ramp. Chin. Phys. Lett. 38, 035201.CrossRefGoogle Scholar
White, R.B., Gorelenkov, N., Heidbrink, W.W. & Zeeland, M.A.V. 2010 a Beam distribution modification by Alfvén modes. Phys. Plasmas 17, 056107.CrossRefGoogle Scholar
White, R.B., Gorelenkov, N., Heidbrink, W.W. & Zeeland, M.A.V. 2010 b Particle distribution modification by low amplitude modes. Plasma Phys. Control. Fusion 52, 045012.CrossRefGoogle Scholar
Zonca, F., Briguglio, S., Chen, L., Dettrick, S., Fogaccia, G., Testa, D. & Vlad, G. 2002 Energetic particle mode stability in tokamaks with hollow q-profiles. Phys. Plasmas 9 (12), 49394956.CrossRefGoogle Scholar
Zonca, F. & Chen, L. 2008 Radial structures and nonlinear excitation of geodesic acoustic modes. Europhys. Lett. 83 (3), 35001.CrossRefGoogle Scholar
Zonca, F., Chen, L., Briguglio, S., Fogaccia, G., Milovanov, A.V., Qiu, Z., Vlad, G. & Wang, X. 2015 a Energetic particles and multi-scale dynamics in fusion plasmas. Plasma Phys. Control. Fusion 57 (1), 014024.CrossRefGoogle Scholar
Zonca, F., Chen, L., Briguglio, S., Fogaccia, G., Vlad, G. & Wang, X. 2015 Nonlinear dynamics of phase space zonal structures and energetic particle physics in fusion plasmas. New J. Phys. 17 (1), 013052.CrossRefGoogle Scholar
Zonca, F., Chen, L., Falessi, M.V. & Qiu, Z. 2021 Nonlinear radial envelope evolution equations and energetic particle transport in tokamak plasmas. J. Phys.: Conf. Ser. 1785, 012005.Google Scholar
Zonca, F., Romanelli, F., Vlad, G. & Kar, C. 1995 Nonlinear saturation of toroidal Alfvén eigenmodes. Phys. Rev. Lett. 74 (5), 698.CrossRefGoogle ScholarPubMed