3.1. Global energisation and parametric dependence

We will start by investigating the energisation models on large scales. The temporal evolution of $\boldsymbol{J}_e\cdot \boldsymbol{E}$ is shown in figure 1, for the $m_i/m_e=25$ , $B_g=0$ run. The evolution is qualitatively similar for all runs. As reconnection starts and magnetic islands start to form (figure 1 a), patches of positive $\boldsymbol{J}_e\cdot \boldsymbol{E}$ are found at the x-points and the edges of the magnetic islands. The total contribution of the different energisation terms in (1.2) and (1.3) over the whole simulation domain for this time are shown in figures 2(a) and 2(b), marked by the first vertical line. We find that the curvature/Fermi term $W_{\textrm{curv0}}$ is the dominant contributor to $\boldsymbol{J}_e\cdot \boldsymbol{E}$ in the LGCM, while the diamagnetic term $W_{\textrm{diam}}$ dominates in the EFM. The dominance of these two terms is consistent with the previous studies by Dahlin et al. (Reference Dahlin, Drake and Swisdak2014) and TenBarge et al. (Reference TenBarge, Juno and Howes2024).

Figure 1. Snapshots of $\boldsymbol{J}_e\cdot \boldsymbol{E}$ for the $m_i/m_e=25$ , $B_g=0$ run at three different times $t\omega _{ci\infty }\in \{8.7,11.3,16.0\}$ , where $\omega _{ci\infty }=\omega _{ce\infty }m_e/m_i$ . The black lines are contours of the vector potential component $A_z$ .

As the system develops further (figure 1 b), the islands contract, coalesce and move with the embedding plasma flow. Locally, $\boldsymbol{J}_e\cdot \boldsymbol{E}$ varies depending on the local island dynamics. The largest values of $\boldsymbol{J}_e\cdot \boldsymbol{E}$ are found in narrow regions at the magnetic island edges. These regions are associated with local contraction of the island, and Fermi-like processes are expected to occur there (Drake et al. Reference Drake, Swisdak, Che and Shay2006a ; Dahlin et al. Reference Dahlin, Drake and Swisdak2014). Similar regions of negative $\boldsymbol{J}_e\cdot \boldsymbol{E}$ correspond to local expansion of the island. Consequently, islands that are convecting have a bipolar $\boldsymbol{J}_e\cdot \boldsymbol{E}$ signature, where the leading edge (locally expanding) is negative, and the trailing edge (locally contracting) is positive. At $t\omega _{ci\infty }=11.3$ (second vertical lines in figures 2 a and 2 b), the LGCM finds that the Fermi-related $W_{\textrm{curv0}}$ is indeed large, while $W_\parallel$ gives a slight negative contribution to $\boldsymbol{J}_e\cdot \boldsymbol{E}$ together with $W_{\textrm{beta-gradB}}$ . In the case of the EFM, $W_{\textrm{diam}}$ is still large, but now there are also significant net contributions from $W_{\textrm{curv1}}\gt 0$ , $W_\parallel \lt 0$ and $W_{\textrm{agyro}}\lt 0$ , showing that multiple fluid drifts contribute to the net energisation. The same general picture remains valid as the islands continue to grow and merge (figure 1 c).

Figure 2. Time evolution of energisation terms summed over the whole domain (arbitrary units) for different $m_i/m_e\in \{25,100\}$ and $B_g/B_\infty \in \{0,0.2,1\}$ as labelled in the panels. The left column shows the guiding centre model results from (1.2) and the right column the corresponding fluid model results from (1.3). The three vertical dashed lines in panels (a) and (b) correspond to the times of the panels in figure 1. Note that we plot a shorter time interval for the $m_i/m_e=100$ simulations in panels (g–j). The y-axis of panel (g) has been limited to better show the deviation between $\boldsymbol{J}_e\cdot \boldsymbol{E}$ and the LGCM sum. All data have been smoothed using a moving average with a window of $\pm 1\omega _{ci\infty }^{-1}$ to reduce noise.

Looking at the temporal evolution of the $W$ -terms in figures 2(a) and 2(b), we find that the LGCM generally provides a qualitative approximation of $\boldsymbol{J}_e\cdot \boldsymbol{E}$ (compare the purple and the dashed black curves), particularly during the time interval $t\omega _{ci\infty }\in (7,18)$ when $\boldsymbol{J}_e\cdot \boldsymbol{E}$ is large. However, at times, the relative difference between the LGCM sum and $\boldsymbol{J}_e\cdot \boldsymbol{E}$ exceeds $80\ \%$ . Integrating over the duration of the simulation reduces the relative difference to approximately $10\ \%$ . In the EFM case, the agreement between the sum of the $W$ -terms and $\boldsymbol{J}_e\cdot \boldsymbol{E}$ is almost perfect. These results are consistent with those from TenBarge et al. (Reference TenBarge, Juno and Howes2024) in the single x-point case.

The remaining panels in figure 2 show the results of the same analysis applied to four other simulations with varying mass-ratio and guide field. Figures 2(c) and 2(d) show the case with moderate guide field $B_g=0.2$ , at the same mass ratio $m_i/m_e=25$ . There, the LGCM performs somewhat better than in the $B_g=0$ , $m_i/m_e=25$ case discussed previously, and the betatron $W_{\textrm{beta-gradB}}$ term is slightly less important than before. In the EFM case, we find that the increased $B_g$ almost removes the curvature contribution entirely and the agyrotropic contribution also becomes less important. This is expected since including an out-of-plane magnetic field component reduces the magnetic curvature across the current sheet and, consequently, the curvature drift. In addition, the guide field contributes to keeping the electrons magnetised (e.g. Swisdak et al. Reference Swisdak, Drake, Shay and McIlhargey2005; Scudder et al. Reference Scudder, Karimabadi, Daughton and Roytershteyn2015), reducing the agyrotropic pressure carried by demagnetised electrons. Increasing the guide field to $B_g=1$ (figures 2 e and 2 f) further improves the accuracy of the LGCM to a very good agreement with $\boldsymbol{J}_e\cdot \boldsymbol{E}$ . The relative contribution of $W_{\textrm{curv0}}$ decreases, while $W_\parallel$ , which for lower $B_g$ was a negative contributor to $\boldsymbol{J}_e\cdot \boldsymbol{E}$ , becomes large and positive. Analogously, in the EFM (figure 2 f), $W_{\textrm{diam}}$ decreases and $W_\parallel$ becomes the largest energisation term, albeit still comparable to $W_{\textrm{diam}}$ . The increased importance of $W_\parallel$ in the LGCM for increasing guide fields was previously reported by Dahlin et al. (Reference Dahlin, Drake and Swisdak2016).

Increasing the mass ratio to $m_i/m_e=100$ does not change the results significantly. In the $B_g=0$ case, the LGCM results (figure 2 g) are qualitatively very similar to the $m_i/m_e=25$ case (figure 2 a), with $W_{\textrm{curv0}}$ being the dominant positive contributor, while $W_\parallel$ and $W_{\textrm{beta-gradB}}$ are negative. In the EFM case (figure 2 h), the relative contribution of $W_{\textrm{curv1}}$ is noticeably smaller than in the $m_i/m_e=25$ case, while the other terms are less affected by the $m_i/m_e$ change. Finally, in the $B_g=0.2$ case (figures 2 i and 2 j), the increased mass ratio does not affect the relative importance of terms in either of the models (cf. figures 2 c and 2 d).

In summary, we conclude that the domain-integrated LGCM is generally dominated by $W_{\textrm{curv0}}$ and the EFM is generally dominated by $W_{\textrm{diam}}$ when $B_g\leqslant 0.2$ . Increasing the guide field to $B_g=1$ leads to $W_\parallel$ becoming larger than (or comparable to) $W_{\textrm{curv0}}$ and $W_{\textrm{diam}}$ . The only significant $m_i/m_e$ dependence is found for the Eulerian $W_{\textrm{curv1}}$ , which becomes less important in the $B_g=0$ case as $m_i/m_e$ is increased from 25 to 100. While the EFM accurately reproduces the total $\boldsymbol{J}_e\cdot \boldsymbol{E}$ over the simulation domain for all runs, we find that the LGCM estimate of electron energisation agrees better with $\boldsymbol{J}_e\cdot \boldsymbol{E}$ for increasing values of $B_g$ . Since the LGCM assumes $\mu$ -conservation, and a larger $B_g$ leads to stronger magnetisation, this result hints that the deviation between the LGCM and $\boldsymbol{J}_e\cdot \boldsymbol{E}$ is related to the presence of non-adiabatic electrons.

Similarly to TenBarge et al. (Reference TenBarge, Juno and Howes2024), we find that the local and volume-integrated pictures of electron energisation are very different. Next, we will investigate the spatial distribution of $\boldsymbol{J}_e\cdot \boldsymbol{E}$ and the energisation terms for the $m_i/m_e=25$ case in more detail.

3.2. Local differences between the LGCM and EFM descriptions

The spatial structures of $\boldsymbol{J}_e\cdot \boldsymbol{E}$ and the $W$ -terms of (1.2) and (1.3) are shown in figure 3. The left column shows the results of the $B_g=0$ simulation at $t\omega _{ci\infty }=16$ . As was seen in figure 1, we find the strongest $\boldsymbol{J}_e\cdot \boldsymbol{E}$ at the edges of the magnetic islands (figures 3 a and 3 b) and we will focus our attention to these regions.

In the LGCM, $W_{\textrm{curv0}}$ (figure 3 c, red) is the dominant energisation term due to the strong magnetic curvature associated with the island. In the Eulerian view, the strong diamagnetic drift associated with the pressure gradient at the island edges results in significant $W_{\textrm{diam}}$ (figure 3 d, magenta), which is the main contributor to $\boldsymbol{J}_e\cdot \boldsymbol{E}$ . Approaching the island from the left, the sum of the energisation terms in (1.2) and (1.3) (black dashed lines in figures 3 c and 3 d) are both in good agreement with $\boldsymbol{J}_e\cdot \boldsymbol{E}$ (purple) until around $x/d_{i0}\approx 9.8$ , marked by the dash-dotted vertical line. After this point, $\boldsymbol{J}_e\cdot \boldsymbol{E}$ starts to decrease. This is well captured by the EFM, which reveals a decreasing $W_{\textrm{diam}}$ while $W_{\textrm{curv1}}\approx -W_{\textrm{agyro}}$ . In contrast, the LGCM deviates from $\boldsymbol{J}_e\cdot \boldsymbol{E}$ by predicting further energsation deeper into the island as a result of a large $W_{\textrm{curv0}}$ . Analogous results (with opposite signs) are obtained for the right edge of the island where $\boldsymbol{J}_e\cdot \boldsymbol{E}$ has a negative peak.

Figure 3. Spatial dependence of $\boldsymbol{J}_e\cdot \boldsymbol{E}$ and the $W$ terms inside magnetic islands for $B_g=0$ (left column) and $B_g=0.2$ (right column). (a) $\boldsymbol{J}_e\cdot \boldsymbol{E}$ for the whole simulation domain. (b) $\boldsymbol{J}_e\cdot \boldsymbol{E}$ for the magnetic island boxed in panel (a). The black lines are contours of $A_z$ . The dashed green lines show the y-range in which the data in panels (c) and (d) are averaged. (c) The different terms in the guiding centre model (1.2) as a function of $x$ . (d) Same as panel (c) for the fluid model (1.3). The vertical dash-dotted line indicates where the LGCM and $\boldsymbol{J}_e\cdot \boldsymbol{E}$ start to qualitatively deviate. The data in panels (c) and (d) have been averaged in $y$ over the interval marked by the dashed green lines in panel (b), and smoothed in $x$ by a moving mean of window size $\pm 0.5d_{e0}$ . (f–h) Same format as panel (a–d) for the $B_g=0.2$ case.

In the $B_g=0.2$ case (right column of figure 3), the LGCM works better than in the $B_g=0$ case, but it still predicts energisation slightly deeper into the island than the measured $\boldsymbol{J}_e\cdot \boldsymbol{E}$ . In both cases, $W_{\textrm{curv0}}$ is the dominant term. The EFM remains accurate, with the main difference being that $W_{\textrm{curv1}}$ is less important than in the $B_g=0$ case. The local differences between the models brings us to the second question posed in the introduction: why does the LGCM fail inside the islands and what actually happens to the electrons at these locations?

Since the LGCM assumes adiabatic electrons, we start by scrutinising this assumption. One important parameter which can be used to quantify whether the motion of a particle is adiabatic is the so-called adiabaticity parameter $\kappa =\sqrt {r_{\textrm{curv}}/r_{ge}}$ , where $r_{\textrm{curv}}=1/|\boldsymbol{k}|$ is the magnetic curvature radius and $r_{ge}=v_{\perp } m_e/(eB)$ the electron gyroradius (Büchner & Zelenyi Reference Büchner and Zelenyi1989). An electron with $\kappa \lt 1$ experiences strong magnetic field changes over its gyro-orbit and its magnetic moment is not conserved. We note that one may define a generalised adiabaticity parameter, accounting for all spatial variations of $\mathbf{B}$ . We do that in Appendix A for reference, but since the alternative definition does not affect the following discussion qualitatively, we will continue using the more widely used definition, given above.

In figures 4(a), 4(b) and 4(c), we present $|\boldsymbol{J}_e\cdot \boldsymbol{E}|$ , the sum of the right-hand side of (1.2), $|W_{\textrm{LGCM}}|$ and $|W_{\textrm{LGCM}}/\boldsymbol{J}_e\cdot \boldsymbol{E}|$ for the $B_g=0$ case. The largest relative discrepancies between the LGCM and $\boldsymbol{J}_e\cdot \boldsymbol{E}$ are found at the x-points and in the centre of the magnetic islands (figure 4 c), where $|W_{\textrm{LGCM}}|$ is up to a few orders of magnitude larger than $|\boldsymbol{J}_e\cdot \boldsymbol{E}|$ . These locations are regions where the thermal $\kappa$ (using $v_{te \perp }=\sqrt {2T_{e\perp }/m_e}$ in $r_{ge}$ ) is very small ( $\kappa \ll 1$ ), as shown in figure 4(d). Since $\kappa \ll 1$ implies non-adiabatic electron motion, we conclude that the deviations in these regions can likely be attributed to the erroneous assumption of $\mu$ conservation made by the LGCM. The fact that electrons can exhibit non-adiabatic behaviour during magnetic reconnection is well known (Zenitani & Nagai Reference Zenitani and Nagai2016), and the failure of the LGCM near the current sheet centre and at the x-points in the low- $B_g$ limit is not surprising. In other regions, the error does not correlate well with $\kappa$ . One such example is the separatrices of the larger reconnection sites. There, the LGCM deviates from $\boldsymbol{J}_e\cdot \boldsymbol{E}$ even though $\kappa \gg 1$ .

Figure 4. Deviations from $\boldsymbol{J}_e\cdot \boldsymbol{E}$ in the LGCM for (a–d) $B_g=0$ and (e–h) $B_g=0.2$ . Panels (a) and (b) show respectively $\boldsymbol{J}_e\cdot \boldsymbol{E}$ and the sum of the guiding centre model terms in (1.2), $W_{\textrm{LGCM}}$ . Only values larger than $10^{-5}$ have been included. (c) $|W_{\textrm{LGCM}}/\boldsymbol{J}_e\cdot \boldsymbol{E}|$ using the data in panels (a) and (b). The thick black contour shows the $\kappa =1$ threshold, where the bounded regions contain $\kappa \lt 1$ . The colourbar is saturated. (d) The adiabaticity parameter $\kappa$ computed using the perpendicular thermal speed. Blue regions correspond do $\kappa \lt 1$ , i.e. where the motion of thermal electrons is not adiabatic, and red regions to $\kappa \gt 1$ . The colourbar has been limited to the range $\log _{10}(\kappa )\in [-0.5,0.5]$ to highlight the adiabatic/non-adiabatic transition. (e–h) Same format as panel (a–d) for the $B_g=0.2$ case.

In the $B_g=0.2$ case, the presence of the out-of-plane component leads to a reduced magnetic curvature (i.e. a larger $r_{\textrm{curv}}$ ), and we generally find $\kappa \gg 1$ (figure 4h). Small values of $\kappa$ are still found near the x-points and $\kappa$ occasionally drops below 1. It should be noted that the plotted $\kappa$ is for thermal electrons and electrons with $v_\perp \gt v_{te\perp }$ have smaller $\kappa$ . A large fraction of the electrons might therefore be non-adiabatic when the thermal $\kappa \approx 1$ . The fact that there are still significant deviations even though $\kappa \gt 1$ (figures 3 g and 4 h) suggests that there is another issue at play other than the lack of $\mu$ -conservation. This suspicion is reinforced by the fact that the LGCM locally deviates from $\boldsymbol{J}_e\cdot \boldsymbol{E}$ even in the $B_g=1$ case (see Appendix B), where $\kappa \gg 1$ everywhere.

We conclude that the non-adiabatic motion of electrons near x-points and the current sheet centre, particularly in the $B_g=0$ case, is a large source of error in the LGCM. However, this is not the entire picture, and there is still the issue of the transition between the Lagrangian and Eulerian frameworks when (1.2) is evaluated on an Eulerian grid. This problem was discussed by TenBarge et al. (Reference TenBarge, Juno and Howes2024), and in the following section, we will expand on their discussion to pin-point the issue and illustrate how this affects the local electron energisation estimate.

3.3. Eulerian versus Lagrangian energisation

Specifically, the problem with evaluating (1.2) on an Eulerian grid (assuming $\mu$ is conserved) is that it gives the impression that it provides an Eulerian view on electron energisation, i.e. that it describes the evolution of the total electron energy within a fixed volume element. However, (1.2) is derived in a Lagrangian framework from the single guiding centre equation (1.1), which describes the rate of energy gain a single guiding centre experiences at some given time. To derive (1.2) from (1.1), one takes a small volume (such that all charges experience the same fields) and adds up (1.1) for all guiding centres within the volume. Thus, what the quantity ${\rm d}\mathcal{E}_{\textrm{LGCM}}/{\rm d}t$ in (1.2) describes is the rate of energy gain per unit volume of the specific guiding centres that are currently in the volume element. Importantly, this means that the electron energy flux into or out of the volume is irrelevant for ${\rm d}\mathcal{E}_{\textrm{LGCM}}/{\rm d}t$ . This detail distinguishes the Lagrangian description from the Eulerian description, which is concerned with the evolution of the total electron energy content within the volume. The Eulerian electron energy equation therefore contains divergence terms related to the electron energy flux:

(3.1) \begin{equation} \frac {\partial \mathcal{E}_{\textrm{EFM}}}{\partial t} + \nabla \cdot \left (\boldsymbol{K}+\boldsymbol{H}+\boldsymbol{q}\right ) = \boldsymbol{J}_e\cdot \boldsymbol{E}, \end{equation}

where $\mathcal{E}_{\text{EFM}}=m_en_eu_e^2/2+\text{trace}(\mathbf{P}_e)/2:=K+U$ is the total electron energy density with $K$ and $U$ being respectively the bulk kinetic and thermal contributions, $\boldsymbol{K}=K\boldsymbol{u}_e$ is the kinetic energy flux density, $\boldsymbol{H}=U\boldsymbol{u}_e+\mathbf{P}_e\cdot \boldsymbol{u}_e$ is the enthalpy flux density, and $\boldsymbol{q}$ is the heat flux density (e.g. Helander & Sigmar Reference Helander and Sigmar2005). The energy equation describes the evolution of the electron energy density inside a fixed volume element, a quantity that is fundamentally different from the aforementioned Lagrangian ${\rm d}\mathcal{E}_{\textrm{LGCM}}/{\rm d}t$ .

As evident from (3.1), $\boldsymbol{J}_e\cdot \boldsymbol{E}$ is a source term and it can be balanced by the time derivative and divergence (i.e. energy flux density) terms. The importance of the divergence terms on smaller scales is readily seen in figure 5, where the spatial distribution of the different components of (3.1) are shown in panels (a)–(h). The large $\boldsymbol{J}_e\cdot \boldsymbol{E}$ found at the edges of magnetic islands is mainly balanced by the divergence terms in the energy equation (see figures 5 a and 5 h, where $\boldsymbol{Q}=\boldsymbol{K}+\boldsymbol{H}+\boldsymbol{q}$ ), where $\nabla \cdot \boldsymbol{H}$ dominates (figure 5 c) over $\nabla \cdot \boldsymbol{K}$ (figure 5 b) and $\nabla \cdot \boldsymbol{q}$ (figure 5 d). The time derivative terms (figure 5 e–g) tend to have the opposite sign to the divergence terms, and the internal energy term (figure 5 f) dominates over the kinetic energy term (figure 5 g). The large contribution of the energy flux terms, particularly $\nabla \cdot \boldsymbol{H}$ , is consistent with in situ studies of magnetic reconnection (Eastwood et al. Reference Eastwood2020; Fargette et al. Reference Fargette, Eastwood, Waters, Øieroset, Phan, Newman, Stawarz, Goldman and Lapenta2024). We conclude that, on a local level, most of $\boldsymbol{J}_e\cdot \boldsymbol{E}$ is balanced by the electron energy flux densities, with the dominant term being the enthalpy flux density. This is a key reason why the LGCM locally deviates from $\boldsymbol{J}_e\cdot \boldsymbol{E}$ , even when the assumption of magnetic moment conservation is valid.

Figure 5. The contribution of the different terms in (3.1) to $\boldsymbol{J}_e\cdot \boldsymbol{E}$ in the $B_g=0$ , $m_i/m_e=25$ simulation. (a–h) Spatial profiles for the different terms at $t\omega _{ci\infty }=16$ . The top row of panels show the three terms in (3.1), where $\boldsymbol{Q}=\boldsymbol{K}+\boldsymbol{H}+\boldsymbol{q}$ . The first and second columns of panels show the different divergence and time derivative terms, respectively. The divergence terms in panel (a–d) have been smoothed using a 5-point moving average to reduce noise. (i) Time dependence of the different terms summed over the whole simulation domain.

On system scales, however, the picture is very different. For our choice of boundary conditions, the system is closed in the sense that there is no net particle energy flux into or out of the simulation domain. Therefore, when we integrate the divergence terms of (3.1) over the whole simulation, the corresponding surface terms vanish, leaving us with $\boldsymbol{J}_e\cdot \boldsymbol{E}\approx \partial \mathcal{E}_{\textrm{EFM}}/\partial t$ , as seen in figure 5(i). This is why the domain-integrated LGCM can accurately reproduce $\boldsymbol{J}_e\cdot \boldsymbol{E}$ when $\mu$ -conservation applies (figure 2 e). In that case, (1.2) describes the evolution of the total energy of all guiding centres, and since they are confined to the simulation domain, this is the same thing as the evolution of the total electron energy in the simulation domain. So, when we look at a closed system in its entirety, indeed $\int d^3x(d\mathcal{E}_{\textrm{LGCM}}/dt) = \int d^3x(\partial \mathcal{E}_{\text{EFM}}/\partial t)=\int d^3x\boldsymbol{J}_e\cdot \boldsymbol{E}$ . The difference between the domain-integrated LGCM and $\boldsymbol{J}_e\cdot \boldsymbol{E}$ observed in the $B_g=0$ case (figure 2 a) can thus be attributed to the lack of $\mu$ conservation due to the small $\kappa$ (figure 4 d). The fact that the LGCM equation is locally invalid in the $B_g=0$ case explains why the domain-integrated LGCM both overestimates and underestimates $\boldsymbol{J}_e\cdot \boldsymbol{E}$ in the $B_g=0$ case (figure 2 a), and subsequently why the time-integrated energisation more accurately reproduces $\boldsymbol{J}_e\cdot \boldsymbol{E}$ .

Until this point, we have followed TenBarge et al. (Reference TenBarge, Juno and Howes2024) and uncritically assumed that, since ${\rm d}\mathcal{E}_{\textrm{LGCM}}/{\rm d}t$ accurately describes the energisation of individual guiding centres, it must equal the work done on the electrons as quantified by $\boldsymbol{J}_e\cdot \boldsymbol{E}$ . In other words, since we can write (1.2) as the scalar product of a net current density $\boldsymbol{J}_{e,{\textrm{LGCM}}}$ and $\boldsymbol{E}$ , $\boldsymbol{J}_{e,\textrm{LGCM}}$ should be equal to the bulk fluid current density $\boldsymbol{J}_e$ . This, however, is evidently not the case. As already mentioned by TenBarge et al. (Reference TenBarge, Juno and Howes2024), the guiding centre model is a particle model that is gyroperiod integrated, and it consequently does not describe certain bulk fluid properties such as the diamagnetic drift and the corresponding currents. Therefore, in general, $\boldsymbol{J}_{e,\textrm{LGCM}}\neq \boldsymbol{J}_e$ , since $\boldsymbol{J}_e$ describes the total electron current. In hindsight, it is therefore quite clear that we should never have expected ${\rm d}\mathcal{E}_{\textrm{LGCM}}/{\rm d}t$ to accurately model $\boldsymbol{J}_e\cdot \boldsymbol{E}$ to begin with, even when $\mu$ is conserved.

Finally, we note that while (1.2) is derived in the Lagrangian framework, the right-hand terms are expressed in terms of bulk fluid quantities which, in our case, are known on the points defined by the Eulerian grid. It is perfectly valid to evaluate (1.2) on an Eulerian grid (if $\mu$ is conserved); one must just keep in mind that a local measurement of $d\mathcal{E}_{\textrm{LGCM}}/dt$ describes the energy evolution of the guiding centres that are presently in the local volume, not the evolution of the electron energy within the volume. In their paper, TenBarge et al. (Reference TenBarge, Juno and Howes2024) state, regarding the LGCM results, that ‘[…] neither globally nor locally does the sum of the energisation mechanisms agree well with $\boldsymbol{J}_e\cdot \boldsymbol{E}$ , suggesting that the Lagrangian description, unsurprisingly, does not work well in an Eulerian simulation’, which may give the impression that there is an inherent conflict between their Eulerian solver and the LGCM. We want to stress that the inherently Eulerian nature of a continuum Vlasov–Maxwell solver does not affect the applicability of (1.2). The deviations from $\boldsymbol{J}_e\cdot \boldsymbol{E}$ observed by TenBarge et al. (Reference TenBarge, Juno and Howes2024) on a global level can likely be attributed to the demagnetisation of electrons near the x-point, as their choice of $B_g=0.1$ is not large enough to keep the electrons well magnetised (see our $B_g=0.2$ and $B_g=1$ results in figures 2 c and 2 e). The local deviations are likely, as discussed above, a result of the combination of non-conserved $\mu$ and energy fluxes.