2.1. Initial configuration of antiparallel flux tubes

The initial configurations of both vortex tubes and magnetic tubes are similar to the standard antiparallel set-ups commonly used in previous studies (Melander & Hussain Reference Melander and Hussain1989; van Rees et al. Reference van Rees, Hussain and Koumoutsakos2012; Yao & Hussain Reference Yao and Hussain2019) and serve as a suitable model for solar atmospheric vortices, as shown in figure 1. The parametric equations for the centrelines of the two flux tubes are given by

(2.1) \begin{equation} \boldsymbol{c}(s) = \left ( \pm s, y_c(s), z_c(s) \right), \end{equation}

where

(2.2) \begin{equation} y_c(s) = y_0 + p\, f(s) \sin \alpha , \end{equation}

(2.3) \begin{equation} z_c(s) = z_0 + p\, f(s) \cos \alpha . \end{equation}

Here, $(y_0, z_0)$ represent the initial positions of the unperturbed vortex centroids, $s$ is the arc length parameter, $p$ is the amplitude of the axis displacement, and $\alpha$ is the inclination angle. For the symmetric pair of antiparallel tubes, we set $(y_0, z_0) = (\mp 0.81, 0)$ , $\alpha = \pm \pi /3$ , $p = 0.2$ and $f(s) = \cos (s)$ . The initial configuration of centrelines is shown in figure 2.

Figure 2. Initial configuration of antiparallel flux tubes. (a) Initial configuration of the centrelines of flux tubes, shown in perspective, side, top and front views (ordered from left to right, top to bottom). (b) Initial vortex or magnetic surfaces of the antiparallel flux tubes. Some attached field lines (red) are integrated from points on these surfaces.

Building upon a previously developed geometric construction framework (Xiong & Yang Reference Xiong and Yang2019; Shen et al. Reference Shen, Yao, Hussain and Yang2023, Reference Shen, Yao and Yang2024), we generate tailored configurations of the vorticity field $\boldsymbol{\omega }$ and the magnetic field $\boldsymbol{b}$ to represent vortex tubes and magnetic flux tubes with given centreline topology, tube thickness and flux strength. We employ a curvilinear cylindrical coordinate system $(s, r, \theta)$ , where $s$ denotes the arc length along the tube’s centreline $\boldsymbol{c}(s)$ , and $(r, \theta)$ are the local polar coordinates in the cross-sectional plane. In this coordinate system, the fields are prescribed as

(2.4) \begin{equation} \left \lbrace \begin{aligned} &\boldsymbol{\omega }(s, r, \theta) = \varGamma _0\, f_t(r)\, \boldsymbol{e}_{s}, \\ &\boldsymbol{b}(s, r, \theta) = \varGamma _{m0}\, f_t(r)\, \boldsymbol{e}_{s}, \end{aligned} \right . \end{equation}

where $\boldsymbol{e}_{s} \equiv \mathrm{d}\boldsymbol{c}/\mathrm{d}s$ is the unit tangent vector along the tube centreline, and $\varGamma _0$ and $\varGamma _{m0}$ denote the initial flux of vorticity and magnetic induction, respectively. These quantities define the global strength of the respective fields along the tube. The radial distribution of both fields within the tube cross-section is modelled by a Gaussian kernel

(2.5) \begin{equation} f_t(r) = \frac {1}{2\pi \sigma _{c0}^2} \exp \left ( -\frac {r^2}{2 \sigma _{c0}^2} \right), \end{equation}

where the standard deviation $\sigma _{c0} = 0.25$ characterises the initial effective thickness of the flux tubes. This smooth, localised profile ensures well-defined, confined tubular structures, suitable for both analytical and numerical studies.

We ensure that the antiparallel pairs of vortex tubes and magnetic flux tubes are initialised with exactly the same tube thickness and placed at precisely the same initial positions. Under such a configuration, both the vorticity and magnetic field obey their respective frozen-in principles. Small sinusoidal perturbations introduced via (2.1) lead to distinct response modes in the two fields. In vortex tubes, the deformation triggers Crow instability and reconnection through induced motion (Melander & Hussain Reference Melander and Hussain1989). In contrast, magnetic tubes respond through curvature-induced Lorentz forces, which drive tube splitting (Kang et al. Reference Kang, Wang, Jiang, Hao, Xiong, Fan and Cui2025). This set-up enables the charged fluid within the flux tubes to exhibit a competitive interplay between inertial forces and Lorentz forces.

For the initial conditions, we prescribe the vorticity flux of each antiparallel vortex tube pair as

(2.6) \begin{equation} \varGamma = \varGamma _0 = \int _{\mathcal{S}} \boldsymbol{\omega } \boldsymbol{\cdot }\boldsymbol{n} \, \mathrm{d}S = 1, \end{equation}

where $\boldsymbol{\omega }$ is the vorticity vector, and $\mathcal{S}$ denotes a cross-sectional surface of the tube. Subsequently, we superimpose magnetic flux tubes with various magnetic flux strengths given by

(2.7) \begin{equation} \varGamma _m = \varGamma _{m0} = \int _{\mathcal{S}} \boldsymbol{b} \boldsymbol{\cdot }\boldsymbol{n} \, \mathrm{d}S, \end{equation}

at the location of the vortex tubes, where $\varGamma _{m0}$ ranges from 0.02 to 1. Here, $\boldsymbol{b}$ is the dimensionless magnetic induction field, normalised by the Alfvén velocity $\boldsymbol{b} = \boldsymbol{B}/\sqrt {\mu \rho }$ , in which $\boldsymbol{B}$ is the magnetic field, $\rho$ is the fluid density, and $\mu$ is the magnetic permeability of free space.

In this study, we focus primarily on flows characterised by a vortex Reynolds number

(2.8) \begin{equation} {Re}= \frac {u \ell }{\nu } \sim \frac {\varGamma _0}{\nu } = 2000, \end{equation}

and a magnetic Prandtl number $Pr_m = \nu /\eta = 1$ , so that the magnetic Reynolds number becomes

(2.9) \begin{equation} R_m = \frac {u \ell }{\eta } \sim \frac {\varGamma _0}{\eta } = {Re}. \end{equation}

Here, $u$ and $\ell$ denote characteristic velocity and characteristic length, respectively. This ensures that vorticity diffusion due to kinematic viscosity $\nu$ is balanced with magnetic diffusion, where the magnetic diffusivity is given by $\eta = (\sigma \mu)^{-1}$ , and $\sigma$ is the electrical conductivity.

The interaction parameter (Davidson Reference Davidson2015; Kivotides Reference Kivotides2018) quantifies how strongly the magnetic field influences the inertial dynamics of flow structures. It is defined as

(2.10) \begin{equation} N_i = \frac {\boldsymbol{\nabla }\times (\text{Lorentz force})}{\boldsymbol{\nabla }\times (\text{inertial force})} = \frac {\sigma B^2 \ell }{\rho u}, \end{equation}

and represents the dimensionless ratio measuring the relative magnitude of the Lorentz force to the inertial force. A higher value of $N_i$ indicates a stronger magnetic modulation of the vortex-dominated turbulence, marking a departure from purely hydrodynamic behaviour. Substituting $B = b \sqrt {\mu \rho }$ and choosing the tube thickness $\sigma _c$ as the characteristic length scale, we obtain

(2.11) \begin{equation} N_i = \frac {(b \ell ^2)^2}{(u \ell)(\sigma \mu)^{-1} \ell ^2} \sim \frac {\varGamma _m^2}{\varGamma \eta \sigma _c^2} . \end{equation}

In the current study, our choice of parameters spans a broad range of interaction strengths, corresponding to $N_i$ values from $12.8$ to $32\,000$ , thus covering regimes from vorticity-dominated dynamics to those dominated by Lorentz forces.

In the numerical implementation, the construction in (2.4) is realised within a periodic domain of size $(2\pi)^3$ . This is achieved through a differential geometry-based mapping technique (Xiong & Yang Reference Xiong and Yang2019, Reference Xiong and Yang2020; Shen et al. Reference Shen, Yao, Hussain and Yang2023, Reference Shen, Yao and Yang2024), which transforms coordinates from a curvilinear cylindrical system $(s, r, \theta)$ to a Cartesian grid. This approach facilitates the generation of strictly solenoidal vorticity or magnetic fields, thereby ensuring that the initial conditions used in DNS are physically consistent and well posed. This numerical construction has been demonstrated to be highly robust in generating smooth vorticity fields and magnetic fields even in cases of turbulence and complex flux tube interactions (Shen, Yao & Yang Reference Shen, Yao and Yang2024). The initial configuration of the constructed flux tubes is visualised in figure 2(b) via vortex surfaces and magnetic flux surfaces. Each vortex line or magnetic field line lies precisely embedded within the corresponding vortex or magnetic surface.

The velocity field $\boldsymbol{u}$ is then obtained from the prescribed vorticity field $\boldsymbol{\omega }$ via the Biot–Savart law, which is implemented in Fourier space for computational efficiency. The relationship is given by

(2.12) \begin{equation} \boldsymbol{u} = \mathcal{F}^{-1}\left (\frac {{\rm i} \boldsymbol{k} \times \hat {\boldsymbol{\omega }}}{|\boldsymbol{k}|^2}\right), \end{equation}

where $\mathcal{F}^{-1}$ denotes the inverse Fourier transform, $\boldsymbol{k}$ is the wavevector in Fourier space, and $\hat {\boldsymbol{\omega }} = \mathcal{F}(\boldsymbol{\omega })$ represents the Fourier transform of the vorticity field.

2.2. Direct numerical simulation of MHD flows

We solve the three-dimensional incompressible MHD equations (Gurnett & Bhattacharjee Reference Gurnett and Bhattacharjee2017) with a constant unit density $\rho$ . The first is the fluid momentum equation

(2.13) \begin{equation} \frac {\partial \boldsymbol{u}}{\partial t} + \boldsymbol{u} \boldsymbol{\cdot }\boldsymbol{\nabla }\boldsymbol{u} = -\boldsymbol{\nabla }\left (\frac {p}{\rho }\right) + \boldsymbol{j} \times \boldsymbol{b} + \nu\, {\nabla} ^2 \boldsymbol{u}. \end{equation}

The evolution of the magnetic field $\boldsymbol{b}$ is governed by the induction equation

(2.14) \begin{equation} \frac {\partial \boldsymbol{b}}{\partial t} = \boldsymbol{\nabla }\times (\boldsymbol{u} \times \boldsymbol{b}) + \eta\, {\nabla} ^2 \boldsymbol{b}. \end{equation}

The incompressibility conditions $\boldsymbol{\nabla }\boldsymbol{\cdot }\boldsymbol{u} = 0$ and $\boldsymbol{\nabla }\boldsymbol{\cdot }\boldsymbol{b} = 0$ are enforced. Here, $\boldsymbol{x} = (x, y, z)$ denotes the Cartesian spatial coordinates, $\boldsymbol{j} = \boldsymbol{\nabla }\times \boldsymbol{b}$ is the current density, and $p$ is the pressure. Furthermore, the evolution of vorticity field $\boldsymbol{\omega } = \boldsymbol{\nabla }\times \boldsymbol{u}$ can be described by

(2.15) \begin{equation} \frac {\partial \boldsymbol{\omega }}{\partial t} = \boldsymbol{\nabla }\times (\boldsymbol{u} \times \boldsymbol{\omega }) + \nu\, {\nabla} ^2 \boldsymbol{\omega } + \boldsymbol{\nabla }\times (\boldsymbol{j} \times \boldsymbol{b}). \end{equation}

Notably, aside from the Lorentz force contribution in the final term, the structure of this equation mirrors that of the magnetic induction (2.14), highlighting the formal analogy between vorticity dynamics and magnetic field evolution in MHD.

Direct numerical simulations (DNS) of MHD flows are performed in a triply periodic cubic domain $\varOmega$ , discretised using $N^3$ uniform grid points. We employ a pseudo-spectral method to solve (2.13) and (2.14) in the symmetric Elsässer form $\boldsymbol{z}^{\pm } = \boldsymbol{u} \pm \boldsymbol{b}$ (Elsässer Reference Elsässer1950). Aliasing errors are mitigated using the two-thirds truncation rule, restricting the maximum resolved wavenumber to $k_{max } \approx N/3$ . Time advancement of Fourier coefficients is achieved using a second-order Runge–Kutta scheme. The time step is chosen to ensure that the Courant–Friedrichs–Lewy (CFL) numbers are below 0.5 for both the velocity and magnetic fields, thereby ensuring numerical stability and accuracy throughout the simulation. This numerical solver has been used and validated in magnetic reconnection (Hao & Yang Reference Hao and Yang2021). Time is non-dimensionalised as $t^*=t / (2 \pi l_s^2 / \varGamma _0)$ , where $l_s = 1.62$ is the initial separation between vortex tubes, and $\varGamma _0$ is the initial circulation of either tube. This scaling implies that $t^*$ approximately represents the time taken for the undisturbed vortex dipole to travel a distance $l_s$ .

To ensure that the grid resolution can fully resolve the flow evolution, the grid number $N$ is carefully selected in the range 512–1024 based on the case under consideration. A grid convergence analysis is detailed in the Appendix for a vortex–magnetic joint reconnection case at different Reynolds numbers, which has the most demanding resolution requirements due to the strong gradients in both velocity and magnetic fields.

4.1. Vortex-dominated joint reconnection for low $N_i$

In the regime of low interaction parameter $N_i$ , vortex dynamics prevails. Small initial perturbations can trigger the Crow instability in vortex tubes, which serves as the primary mechanism driving reconnection at low $N_i$ . Perturbations to magnetic flux tubes can lead to their straightening or splitting. However, when $N_i$ is small, the Lorentz force is weak relative to the vortex-induced flow, and plays little role in initiating either the instability or reconnection. Under the influence of the frozen-in law, magnetic field lines are advected by the motion of vortex structures. Figures 5(a,b) illustrate the evolution of both vortex and magnetic structures during a vortex–magnetic joint reconnection at ${Re}=R_m=2000$ and $N_i=12.8$ . The vorticity and magnetic field are tightly coupled, exhibiting a strong Lagrangian coherence.

Figure 5. Evolution of flow structures for vortex–magnetic joint reconnection at ${Re}=R_m=2000$ and $N_i=12.8$ , visualised through volume rendering of (a) vorticity magnitude $|\boldsymbol{\omega }|$ and (b) magnetic induction magnitude $|\boldsymbol{b}|$ .

Vortex dynamics, governed by the frozen-in nature of vorticity, dominate the flow. Vortex tubes entrain magnetic flux tubes, lifting them upwards and initiating simultaneous vortex and magnetic reconnections. This joint reconnection process imparts to magnetic reconnection the same complex structural features typically seen in vortex reconnection – namely, bridging and threading (Melander & Hussain Reference Melander and Hussain1989; Yao & Hussain Reference Yao and Hussain2022), where the main flux tubes reconnect and leave behind fine-scale thread-like structures. This contrasts with typical magnetic reconnection, which is generally much simpler, often fast and clean (Hao & Yang Reference Hao and Yang2021). Classical models, often based on current sheets (Yamada, Kulsrud & Ji Reference Yamada, Kulsrud and Ji2010; Pontin & Priest Reference Pontin and Priest2022), capture large-scale reconnection but neglect vorticity and interaction effects, thus missing finer structural features.

Magnetic reconnection occurs primarily within current sheets, where electric current density concentrates. As reconnection proceeds, the current increases sharply at the reconnection site. Figure 6(a) shows the evolution of the current density magnitude $|\boldsymbol{j}|$ on the $y$ – $z$ symmetry plane. Vorticity isolines mark the positions and boundaries of the flux tubes. Driven by vortex advection, high current density layers emerge at the contact interface of the flux tubes. According to Ampère’s law, this corresponds to intense magnetic field variation $\boldsymbol{\nabla }\times \boldsymbol{b} = \boldsymbol{j}$ . Figure 6(b) presents the three-dimensional structure and spatial location of the current sheets. A disk-shaped current sheet forms at the interface between approaching vortex tubes. Electric current penetrates this sheet from below and exits above, while magnetic field lines reconnect within the sheet.

Figure 6. Formation of current sheets during reconnection. (a) Evolution of current density magnitude $|\boldsymbol{j}|$ shown as colour contours, with vorticity magnitude $\boldsymbol{\omega }$ overlaid as isolines on the $y$ – $z$ symmetry plane before and during the reconnection process. (b) Three-dimensional structure of the current sheet and magnetic flux tubes at $t^* = 1.82$ . The white isosurface represents the magnetic field magnitude $|\boldsymbol{b}| = 0.01$ , outlining the outer boundary of the flux tubes. Selected magnetic field lines are shown on this surface. The red isosurface corresponds to $|\boldsymbol{j}| = 0.15$ , highlighting the high-current region seen in (a).

Figure 7. Temporal evolution of volume-averaged energies for the reconnection case with $N_i = 12.8$ : (a) kinetic energy and its time derivative; (b) magnetic energy and its time derivative.

The evolution of the flow also governs the energy balance of the system. Under a low interaction parameter $N_i$ , the kinetic energy significantly exceeds the magnetic energy. As shown in figure 7(a), the kinetic energy decreases monotonically throughout the global flow, and the influence of the magnetic field on this decay is negligible. Vortex reconnection is a highly dissipative process, rapidly reducing the kinetic energy. Surprisingly, the magnetic energy increases during the reconnection process, and reaches its maximum after reconnection is completed (see figure 7 b). The total electromechanical energy in the system, defined as the sum of kinetic and magnetic energies, decreases due to Ohmic heating and viscous dissipation:

(4.1) \begin{equation} \frac {\mathrm{d} E}{\mathrm{d} t} = \frac {\textit{d}}{\mathrm{d} t} \int _V \left [ \frac {\boldsymbol{u}^2}{2} + \frac {\boldsymbol{b}^2}{2} \right ] {\rm d}V = - \int _V ( \eta \boldsymbol{j}^2)\, {\rm d}V - 2 \nu \int _V S_{ij} S_{ij} \, {\rm d}V, \end{equation}

where $S_{ij}$ is the strain-rate tensor. Given that kinetic energy and magnetic energy are the only forms of energy contributing to this balance, the observed increase in magnetic energy implies a conversion of kinetic energy into magnetic energy via vortex-induced magnetic reconnection. This phenomenon can be viewed as a manifestation of the dynamo effect, which is often of central interest in the interiors of the Sun and stars. This contrasts sharply with the canonical magnetic reconnection observed at the solar surface, where oppositely directed magnetic field lines break and reconnect, rapidly converting magnetic energy into kinetic energy. In the solar atmosphere, this released energy drives high-energy particle jets and generates radiation.

Understanding the physical mechanism behind the vortex-induced growth of magnetic energy is crucial for gaining deeper insight into the dynamo effect. The evolution of magnetic energy is governed by the equation

(4.2) \begin{equation} \frac {\textit{d}}{\mathrm{d} t} \int _V \left ( \frac {\boldsymbol{b}^2}{2} \right) {\rm d}V = - \int _V \bigl[ (\boldsymbol{j} \times \boldsymbol{b}) \boldsymbol{\cdot }\boldsymbol{u} \bigr]\, {\rm d}V - \int _V ( \eta \boldsymbol{j}^2)\, {\rm d}V, \end{equation}

where the term involving the Lorentz force represents the work done on the plasma. The conversion from kinetic to magnetic energy occurs when the Lorentz force performs negative work $\mathcal{W}_{{L}} = \int _{V}\bigl[(\boldsymbol{j} \times \boldsymbol{b}) \boldsymbol{\cdot }\boldsymbol{u}\bigr]\, \mathrm{d} V \lt 0$ . Figure 8(a) highlights the regions with negative $\mathcal{W}_{{L}}$ during reconnection, localising the magnetic energy growth to flux tubes and slender thread-like structures near the reconnection region.

Figure 8. Regions and mechanisms of magnetic energy growth during vortex-magnetic joint reconnection. (a) The green isosurface of $\mathcal{W}_{{L}} = -1 \times 10^{-4}$ encloses regions where the Lorentz force performs negative work, located near the reconnection sites, and stretched as reconnection proceeds. (b) Schematic of a magnetic flux tube and the Lorentz force on its magnetic surface before and after stretching. Red arrows indicate the Lorentz force at the cross-section. As flux tubes are stretched into slender threads, the Lorentz force performs negative work, contributing to magnetic energy growth.

For a Gaussian-distributed magnetic flux tube (2.4), the Lorentz force is given by

(4.3) \begin{equation} \boldsymbol{F}_{\text{L}} = (\boldsymbol{\nabla }\times \boldsymbol{b}) \times \boldsymbol{b} = \frac {\varGamma _m^2 r}{4 \pi ^2 \sigma _c^6} \exp \left ( -\frac {r^2}{\sigma _c^2} \right) \boldsymbol{e}_r, \end{equation}

where the Lorentz force points radially outwards within the flux tube. During reconnection, vortex tubes stretch the magnetic tubes into slender threads, and as the material surfaces retract, the Lorentz force continuously performs negative work. This sustained mechanism facilitates the conversion of kinetic energy into magnetic energy. Figure 8(b) schematically illustrates this physical process.

The Reynolds number effect on reconnection plays a critical role in modulating the efficiency and characteristics of the vortex-induced dynamo mechanism. Much like in standard vortex reconnection (Yao & Hussain Reference Yao and Hussain2019), increasing the Reynolds number leads to multi-stage reconnection of fine-scale threads. As illustrated in figure 9(a), during reconnection at a higher Reynolds number ( ${Re}= 3000$ ), secondary reconnection occurs among the residual threads following the initial reconnection of the primary flux tubes. This process generates progressively finer vortex and magnetic structures. Notably, as the Reynolds number increases, symmetry breaking emerges at late times. This results from mutual induction and stretching between the residual threads, which form a dipole structure at their upper ends (Yao & Hussain Reference Yao and Hussain2019). The adjacent, elongated tails create a planar, jet-like shear layer that becomes highly susceptible to Kelvin–Helmholtz instability, a mechanism also observed in previous high-Reynolds-number hydrodynamic reconnection studies (e.g. van Rees et al. Reference van Rees, Hussain and Koumoutsakos2012; Beardsell, Dufresne & Dumas Reference Beardsell, Dufresne and Dumas2016) and now shown to arise in the MHD context as well.

Figure 9. Reynolds number effects in the vortex–magnetic joint reconnection. (a) Evolution of flow structures at ${Re}= R_m = 3000$ , visualised by volume rendering of the vorticity magnitude $|\boldsymbol{\omega }|$ . (b) Temporal evolution of magnetic energy for different Reynolds numbers. (c) Temporal evolution of magnetic energy dissipation rate for different Reynolds numbers. The dashed lines in (b) and (c) indicate the times of peak values of the corresponding quantities, occurring at $t^* = 3.12$ , 3.6, 4.12 and 4.73, from left to right.

At the same time, the peak value of magnetic energy increases with the Reynolds number, as shown in figure 9(b). This indicates that the dynamo effect becomes more pronounced at higher Reynolds numbers, with enhanced conversion of kinetic energy into magnetic energy. The occurrence of successive reconnection events at small scales is further evidenced by multiple peaks in the temporal evolution of both magnetic energy and magnetic dissipation rate (see figure 9 c).

To establish the correlation between the multi-peak behaviour of magnetic energy and the occurrence of secondary reconnections, we analysed the temporal derivatives of the $y$ -direction flux transfer and the magnetic energy, as shown in figure 10. The time derivative of the $y$ -flux exhibits multiple peaks, indicating that flux transfer occurs in a discontinuous manner through successive reconnection events. These peak times mark the characteristic moments of each reconnection stage and are indicated by red dashed lines in figure 10. When compared with the derivative of the magnetic energy, we observe that the reconnection times align closely with the peaks in magnetic energy growth rate. This strong temporal correspondence suggests a causal relationship: each reconnection event directly contributes to a new phase of magnetic energy growth. These secondary reconnections are fundamentally similar to the primary event, only occurring at smaller scales. Therefore, the mechanism of magnetic energy amplification, arising from flux tube stretching, applies equally to each secondary reconnection. As the Reynolds number continues to increase, it is foreseeable that higher-order generations of reconnection will develop, ultimately forming a turbulent cloud avalanche composed of a tangled network of fine-scale vortex and magnetic structures. This results in sustained magnetic energy growth and a cascade of magnetic energy down to ever-smaller spatial scales.

Figure 10. Temporal derivatives of (a) $y$ -direction flux transfer and (b) magnetic energy for vortex–magnetic joint reconnection at ${Re}= R_m = 3000$ and $N_i = 19.2$ . The red dashed lines indicate the characteristic times of successive reconnection events, specifically at $t^* = 3.05, 3.52, 4.01, 4.59$ .

4.2. Instability-triggered cascade for moderate $N_i$

A moderate interaction parameter implies a dynamic balance between vortex dynamics and magnetodynamics. Figure 11 illustrates the evolution of flow structures at moderate values $N_i = 115.2$ and $204.8$ . The magnetic and vortex structures remain visually indistinguishable (not shown), suggesting continued coupling between vorticity and magnetic field lines.

Figure 11. Evolution of flow structures for instability-triggered cascade at (a) $N_i=115.2$ and (b) $N_i=204.8$ , visualised through volume rendering of vorticity magnitude $|\boldsymbol{\omega }|$ .

Unlike the complete reconnection observed at low interaction parameters, flux tubes at intermediate interaction parameters initiate reconnection upon contact, but separate again after transferring only a portion of their flux. This behaviour indicates that flux tubes undergo only partial reconnection in this regime. The portion of the tube that successfully reconnects decreases as the interaction parameter increases. The reconnected segments of the flux tubes reorient perpendicularly relative to their original alignment, forming secondary filamentary structures. These secondary antiparallel filaments, both vortex and magnetic, arise from localised reconnection at the contact region, where oppositely directed fields cancel, and partial fluid exchange occurs. Meanwhile, as the unreconnected portions gradually separate from the contact region, the filaments are stretched and slightly displaced. This leads to a morphological transition of the flux tubes from an initial X-shape to an O-shaped configuration (see figure 11 b), signifying a dynamic balance between magnetic tension and vorticity-induced attraction. The charged fluid in this regime oscillates between the attractive forces generated by vortex dynamics and the damping effect of the magnetic field. Kelvin waves (Leweke et al. Reference Leweke, Le Dizès and Williamson2016) and Alfvén waves (Cramer Reference Cramer2011) play a crucial role in this process, inducing instabilities that cause the flux tubes to oscillate and deform as if plucked like a stretched string.

These wave-induced instabilities, combined with nonlinear interactions, give rise to secondary antiparallel filaments. This mechanism iterates, initiating an energy cascade. Analogous to the cascades triggered by Crow instability and elliptical instability in classical vortex dynamics (McKeown et al. Reference McKeown, Ostilla-Mónico, Pumir, Brenner and Rubinstein2020), the flow develops progressively finer structures over time. Both the kinetic and magnetic energy spectra gradually approach the characteristic turbulent scaling, following a Kolmogorov-like spectrum of $k^{-5/3}$ , consistent with observations of solar wind turbulence (Goldstein, Roberts & Matthaeus Reference Goldstein, Roberts and Matthaeus1995; Podesta, Roberts & Goldstein Reference Podesta, Roberts and Goldstein2007), as illustrated in figures 12(a,b).

Figure 12. Temporal evolution of (a) kinetic energy spectra and (b) magnetic energy spectra at $N_i = 115.2$ and ${Re}=2000$ with the $k^{-5/3}$ slope shown as dashed lines. (c,d) The corresponding compensated spectra for kinetic and magnetic energy, respectively, highlighting the overlapping scaling regions ( $k\approx 5{-}8$ ).

Although the kinetic and magnetic energy spectra both exhibit regions consistent with a $k^{-5/3}$ scaling, there is a slight offset between them (see the compensated spectra in figures12 c,d). This mismatch likely reflects differences in the cascade processes of kinetic and magnetic energy, arising from the interplay between vortex distortion and Alfvén wave interactions (Muller & Grappin Reference Muller and Grappin2005; Schekochihin Reference Schekochihin2022). Nevertheless, the scaling regimes of two spectra partially overlap at $k\approx 5 {-} 8$ . Notably, our system has no external energy input, yet the spectra clearly show an increase in small-scale energy over time. This energy growth can only result from a cascade from larger scales, indicating that energy is transferred to smaller scales through repeated generations of filamentation driven by instabilities. As a result, the initially coherent vortex tubes continuously fragment into finer filaments, enriching the small-scale structure of the flow.

4.3. Lorentz-induced vortex disruption for high $N_i$

When the magnetic field becomes dominant, the system enters the regime of large interaction parameters. Figure 13 illustrates the evolution of flow structures, both vortex and magnetic, at a high interaction parameter $N_i = 32\,000$ . In this regime, the initially coupled vortex and magnetic structures begin to decouple, exhibiting clear distinctions in their behaviour. For the vortex structures, the Lorentz force rapidly disrupts their coherence, tearing apart the vortex cores, and deforming them into loosely wound spiral shapes. Moreover, the Lorentz force counteracts the induced motions that would otherwise draw vortex tubes together. As a result, the tubes become isolated, preventing the mutual interactions between antiparallel pairs, such as reconnection and energy cascade, as previously discussed. In contrast, during the early stages, the flux tubes behave similarly to the pure magnetic tubes described in § 3. They rapidly straighten due to magnetic tension. However, the condensation effect of the surrounding vortex field suppresses their tendency to split or fragment. Consequently, over longer time scales, the magnetic tubes largely retain their structure, undergoing gradual dissipation with minimal morphological change.

Figure 13. Evolution of flow structures for Lorentz-induced vortex disruption at $N_i=32\,000$ , visualised through volume rendering of (a) vorticity magnitude $|\boldsymbol{\omega }|$ and (b) magnetic induction magnitude $|\boldsymbol{b}|$ .

Figure 14 presents the contours of axial vorticity $\boldsymbol{\omega }_x$ on cross-sections of the flux tubes, providing a clearer view of the vortex disruption process. Initially, the vortex tubes are stretched and distorted by the Lorentz force, which induces shear and consequently generates reverse vorticity. This reverse vorticity then interleaves with the original vorticity inside the flux tubes, undergoing a global rotation along the streamlines, and ultimately becoming nested and rolled into a complex, spiral structure.

Figure 14. Evolution of axial vorticity $\boldsymbol{\omega }_x$ contours on the $y$ – $z$ symmetry plane before and during the vortex disruption process at $N_i=32\,000$ .

Despite the disruption of vortex tubes, the circulation of both the vortex and magnetic fluxes remains conserved under Helmholtz’s law. Figure 15 illustrates the decomposition of vortex and magnetic fluxes into their positive and negative components. The reverse axial vorticity generated by shearing appears rapidly during vortex core disruption, and is subsequently dissipated (figure 15 a). Simultaneously, the positive circulation grows and dissipates in tandem. However, no significant generation of reverse magnetic field is observed during this process. Furthermore, the negligible flux in the $y$ -direction confirms that interactions between antiparallel tubes are suppressed. As vortex core dissipation progresses, any mutual interactions of antiparallel tubes evolve only slowly.

Figure 15. Temporal evolution of (a,b) vorticity flux and (c,d) magnetic flux for $N_i=32\,000$ , each decomposed into positive and negative contributions, through half of the (a,c) $x = 0$ and (b,d) $y = 0$ planes. All fluxes are normalised by the initial flux in the $x = 0$ plane.

Although the vorticity and magnetic field evolution equations in MHD share structural similarities, they are not identical. The vorticity (2.15) includes an additional source term, the curl of the Lorentz force $\boldsymbol{\nabla }\times (\boldsymbol{j} \times \boldsymbol{b})$ , which acts as a vorticity source induced by magnetic effects. As the interaction parameter increases (i.e. stronger magnetic field), this term becomes more prominent, allowing the Lorentz force to perturb vortex cores and generate significant reverse vorticity. In contrast, the magnetic induction (2.14) lacks a corresponding vorticity-driven source term, so the magnetic field evolution is only weakly affected by the vorticity field. This fundamental asymmetry explains the absence of significant reverse magnetic field generation.

In the regime of high interaction parameters, the energy transfer mechanisms differ fundamentally from those observed at lower $N_i$ . During the initial vortex disruption phase, which occurs over a very short time scale, the Lorentz-force-driven perturbations lead to a partial conversion of magnetic energy into kinetic energy. This is reflected in the rise of kinetic energy and the corresponding decline in magnetic energy (see figures 16 a,d). Subsequently, strong nonlinear interactions emerge, acting as highly dissipative mechanisms for both vorticity and magnetic field structures (figures 16 c,f). During this phase, kinetic and magnetic energies undergo oscillatory decay, primarily due to the rotational wrapping and twisting of core structures. After this intense transient period of nonlinear dynamics, both vortex and magnetic tubes settle into a phase of long-term, stable dissipation, as illustrated in figures 16(b,e). This indicates that the flow is constrained and relaxed by the strong magnetic field, with nonlinear interactions and the onset of turbulence effectively suppressed.

Figure 16. Temporal evolution of volume-averaged quantities for the vortex disruption case with $N_i = 32\,000$ . (a) Kinetic energy and its time derivative during the short-term vortex disruption phase. (b) Kinetic energy and its time derivative during the long-term dissipation phase. (c) Kinetic energy dissipation rate. (d) Magnetic energy and its time derivative during the short-term vortex disruption phase. (e) Magnetic energy and its time derivative during the long-term dissipation phase. (f) Magnetic energy dissipation rate. The orange areas in (b,c) and (e,f) highlight the vortex disruption phase.