2. Optimization

In this work we are interested in the optimization of turbulent transport. Therefore, we want to find favourable geometric configurations which give us a reduced stiffness. We argue that the key effect is the reduction of the effective gradient of the background temperature due to a modified flux expansion. The effect can be understood using the gyro-Bohm scaling of the heat flux for species $\alpha$ through the metric element $g^{xx}$ as

(2.1)\begin{equation} Q_{gB,\alpha} \propto \left(\frac{\rho_\alpha}{L_{T_\alpha,\mathrm{eff}}}\right)^{2} = \rho_\alpha^{2} \left(\frac{ 1}{L_{T_\alpha}}\right)^{2} g^{xx}, \end{equation}

where $1/L_{T_\alpha, \mathrm {eff}} = \sqrt {g^{xx}} /L_{T_\alpha }= |\boldsymbol {\nabla }\ln T_\alpha |$. Here, the radial coordinate is defined as $x=\sqrt {s}$, where $s$ is the normalized toroidal flux and $L_{T_\alpha}, L_{T_\alpha,{\rm eff}}$ are characteristic length scales of the temperature gradient. Physically, (2.1) shows how simply replacing the temperature scale length in the mixing-length estimate of transport can strongly effect the transport. To achieve the reduction of the stiffness, we exploit the effect of flux expansion by minimizing $\left |\boldsymbol {\nabla } s^{2}\right | = ({4 s_0}/{a^{2}}) g^{xx}(z=0)$, where $s$ is the normalized toroidal flux and a is the minor radius, and the gradient is evaluated at the outboard midplane of the configurations. Here, the magnetic field curvature is particularly strong and the ITG and ETG modes are most likely to be destabilized. The optimization produces in our case configurations with minimized $\sqrt {g^{xx}}$. These configurations can then be realized in the W7-X experiment and the effect of the optimization can be evaluated experimentally. The temperature gradient is determined by metric and transport effects and is therefore not directly accessible experimentally.

Starting from the ‘high-mirror’ configuration, the optimization was achieved with the STELLOPT code (Spong et al. Reference Spong, Hirshman, Berry, Lyon, Fowler, Strickler, Cole, Nelson, Williamson and Ware2001) in fixed boundary mode. This set-up allows for more flexibility, with the downside that no information of coil currents is obtained, preventing direct application to experiment. To overcome this, we examined reference W7-X configurations to find a configuration with a similar feature as the optimized configuration. The target function for the optimization is $f=|g^{xx}|^{2}$ at $\theta =\phi =0$ with the polodial and the toroidal Boozer angles, optimizing in the space of Garabedian coefficients $D_{m,n}$ with $|m| \leqslant 4$ and $|n| \leqslant 5$. All other Garabedian coefficients of the boundary were set to zero.

In figure 1(a) the results for the metric coefficient $g^{xx}$ as a function of the parallel coordinate $z$ are shown. Therefore, we study three different W7-X configurations, namely the high-mirror configuration, the optimized configuration and the low-$\iota$ configuration, which shows the smallest metric among the reference W7-X configurations. Here ι is the inverse of the safety factor q. As we see next, a quite substantial reduction of this quantity was achieved for the optimized configuration. The low-$\iota$ configuration shows also a clear reduction compared with the standard high-mirror configuration. In the following, we will show that this successful minimization results also in the reduction of ITG and ETG transport fluxes.

Figure 1. (a) Metric coefficient $g^{xx}$ and (b) ion heat flux produced by ITG turbulence, in gyro-Bohm units $Q_i/Q_{gB}$, as functions of the parallel coordinate $z$, using $a/L_{T_i}=4.0$, for three different W7-X configurations: high-mirror configuration (blue), low-$\iota$ configuration (red) and optimized configuration (green).

3. Turbulence simulations

To investigate the turbulent properties of the chosen magnetic configurations, we performed simulations using the gyrokinetic Vlasov code Gene (Jenko et al. Reference Jenko, Dorland, Kotschenreuther and Rogers2000). This code solves the gyrokinetic equations simultaneously with Maxwell's equations, linearly or nonlinearly. We concentrate on the nonlinear simulations neglecting electromagnetic effects. Thus, we simulate a system with five dimensions where the gyromotion of the particles is eliminated by averaging over the Larmor orbit. The dimension are labelled as follows: $x$ denotes the radial coordinate, $y$ describes the binormal coordinate, $z$ is the parallel coordinate. Apart from the radial coordinate defined above, we have $y={s}/{q} (q\theta -\phi )$ and $z=\theta$. Furthermore, $\mu$ is the magnetic moment, connected to the perpendicular velocity, and $v_\parallel$ is the parallel velocity. The main species for each turbulence type (ITG/ETG) is treated gyrokinetically, while the other one is assumed to have an adiabatic response. Collisions or electromagnetic effects are not considered here.

3.2. The ITG turbulence

Ion temperature gradient turbulence is found in the W7-X experiment (Carralero et al. Reference Carralero, Estrada, Maragkoudakis, Windisch, Alonso, Beurskens, Bozhenkov, Calvo, Damm and Ford2021), and is responsible for strong turbulent heat fluxes, especially for scenarios involving ECRH power. First, we consider the linear simulations shown in figure 2(a). Here, the most unstable linear growth rates for each configuration are displayed over the normalized ITG $a/L_{T_i}$. We can observe that these linear calculations already indicate a lower stiffness for the optimized configuration and the low-$\iota$ configuration. Since only the case $k_x =0$ is studied here, the effect of the metric coefficient is not as prominent as expected. To get further evidence for the reduction, we will look at nonlinear simulations from now on. These are expanded along the radial direction, therefore, a larger distinction between the configurations is expected.

Figure 2. (a) Maximum linear growth rate produced by ITG turbulence, in units of $c_s/a$, as a function of the normalized ITG $a/L_{T_i}$. (b) Maximum linear growth rate produced by ITG turbulence, in units $c_s/a$, as a function of the normalized effective ITG $a/L_{T_{i},\mathrm {eff}}=\sqrt {g^{xx}}/L_{T_i}$ for three different W7-X configurations: high-mirror configuration (blue squares), low-$\iota$ configuration (red triangles) and optimized configuration (green stars).

In figure 1, we show that the flux expansion, mathematically expressed through the metric component $g^{xx}=({a^{2}}/{4s_0}) |\boldsymbol {\nabla } s|^{2}$ correlates well with the calculated ion heat flux from ITG simulations. The maximum heat flux is located at the centre of the tube $z=0$ for all configurations. More importantly, the configurations produce different maximum values of the heat flux according to the magnitude of their corresponding metric coefficient $g^{xx}$ at $z=0$. The high-mirror configuration is characterized by a stronger heat flux compared with the optimized configuration and the low-$\iota$ configuration.

Analysing the dependence of the ion heat diffusivity, in gyro-Bohm units $\chi _i / \chi _{gB}$, with respect to the normalized ITG $a/L_{T_i}=-a/T_i \, {\rm d}T_i/{\rm d}r$, with $r=a \sqrt {s}$, we can compare the three configurations in figure 3. The difference in the resulting scaling is evident in the linear fits. The fit coefficients are listed in table 1. The slope parameter, quantifying ITG turbulence stiffness, is clearly reduced for the optimized configurations. Indeed, the low-$\iota$ configuration has a much smaller stiffness, by almost $33\,\%$, compared with the high-mirror configuration. Not surprisingly, the reduction is even greater for the optimized configuration, where the reduction is approximately $50\,\%$ compared with the initial configuration. On the other hand, the critical gradient does not vary significantly for the three configurations. Therefore, we conclude that minimizing ITG turbulence by the reduction of $g^{xx}$ reduces significantly the stiffness while not affecting the critical gradient.

Figure 3. (a) Ion heat diffusivity produced by ITG turbulence, in gyro-Bohm units ${\chi }_i / \chi _{gB}$, as a function of the normalized ITG $a/L_{T_i}$. (b) Ion heat flux produced by ITG turbulence, in gyro-Bohm units ${Q}_i / Q_{gB}$, as a function of the normalized effective ITG $a/L_{T_{i},\mathrm {eff}}$ for three different W7-X configurations: high-mirror configuration (blue squares), low-$\iota$ configuration (red triangles) and optimized configuration (green stars).

Table 1. Fitted stiffness for ITG turbulence in W7-X configurations.

3.3. The ETG turbulence

Electron temperature gradient turbulence is mostly important when considering ECRH scenarios since the electron temperature gradients become very large while the device is heated (Carralero et al. Reference Carralero, Estrada, Maragkoudakis, Windisch, Alonso, Beurskens, Bozhenkov, Calvo, Damm and Ford2021). Therefore, we performed gyrokinetic simulations for ETG driven turbulence. Here, we excluded the optimized configuration since the calculation is much more resource intensive and the configuration cannot be achieved in the W7-X experiment, and thus is not as relevant for configuration studies for W7-X. Because the parallel variation of the electron heat flux behaves similarly to the ion heat flux, it is not shown here. The results of our scaling studies, similarly to those for ITG, are shown in figure 4. The low-$\iota$ configuration exhibits a much smaller stiffness than the high-mirror configuration. In table 2 one finds that ETG stiffness for the low-$\iota$ configuration is $50\,\%$ of the stiffness for the high-mirror configuration. These results support the expectation that the stellarator optimization done above reduces both ITG and ETG transport fluxes.

Figure 4. (a) Electron heat diffusivity produced by ETG turbulence, in gyro-Bohm units $\chi _e / \chi _{gB}$, as a function of the normalized electron temperature gradient $a/L_{T_e}$. (b) Electron heat flux produced by ETG turbulence, in gyro-Bohm units $Q_e / Q_{gB}$, as a function of the normalized effective electron temperature gradient $a/L_{T_e,\mathrm {eff}}$ for two different W7-X configurations: high-mirror configuration (blue squares) and low-$\iota$ configuration (red triangles).

Table 2. Fitted stiffness for ETG turbulence in W7-X configurations.

5. Summary

We have identified a promising experimental W7-X configuration that shows reduced ITG and ETG transport stiffness compared with the standard high-mirror configuration. To achieve this, we used stellarator optimization, targeting the flux expansion factor. The low-$\iota$ configuration has an exceptionally small flux expansion at regions where the local curvature becomes strong, similar to the numerically optimized configuration. This explains the reduced turbulent heat flux compared with the high-mirror configuration. In particular, we find a reduction of the stiffness of $33\,\%$ for ITG and $50\,\%$ for ETG turbulence as characterized by the slopes of the heat flux plotted versus temperature gradient. We hope that the commissioning of the low-$\iota$ configuration will provide a better performance for the W7-X experiment in the next campaign, particularly alleviating the so-called ‘$T_i$-clamping’ effect.

Finally, we wish to note that the simulation work in this paper has certain restrictions, most importantly the assumption that the density profile is flat. Although this assumption holds well in the core of an ECRH heated plasma, it cannot provide a good approximation for the neutral beam injection  heating or pellet scenarios. In such cases, other micro-instabilities can also grow, such as the trapped electron mode (TEM) and the associated turbulence. Our next work is going to deal with the effect of optimization on TEM turbulence. This work is related to the maximum-J property of the W7-X stellarator (Alcusón et al. Reference Alcusón, Xanthopoulos, Plunk, Helander, Wilms, Turkin, von Stechow and Grulke2020) since the second adiabatic invariant has an high influence on the trapped particles, but it is computationally rather expensive due to the inclusion of kinetic electrons.