A new mechanism for increasing density peaking in tokamaks: improvement of the inward particle pinch with edge <i>E</i> × <i>B</i> shearing

García, J.; Doerk, H.; Görler, T.; Contributors, Jet

doi:10.1088/1361-6587/ab31a4

Cited by 13 publications

(16 citation statements)

References 32 publications

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“…In particular, we notice a significant peaking of the density profile primarily located in the outer regions, thus improving the agreement of the GENE-Tango density profile with the experimental measurements and TGLF-ASTRA. These findings are in agreement with the flux-tube results of reference [85] suggesting that the E × B shear might enhance inward particle pinch.…”

Section: Electrostatic Gene-tango Simulation With Collisions and Exte...supporting

confidence: 92%

Global gyrokinetic simulations of ASDEX Upgrade up to the transport timescale with GENE–Tango

Siena¹,

Navarro²,

Luda³

et al. 2022

Nucl. Fusion

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An accurate description of turbulence up to the transport time scale is essential for predicting core plasma profiles and enabling reliable calculations for designing advanced scenarios and future devices. Here, we exploit the gap separation between turbulence and transport time scales and couple the global gyrokinetic code GENE to the transport-solver Tango, including kinetic electrons, collisions, realistic geometries, toroidal rotation and electromagnetic effects for the first time. This approach overcomes gyrokinetic codes' limitations and enables high-fidelity profile calculations in experimentally relevant plasma conditions, significantly reducing the computational cost. We present numerical results of GENE-Tango for two ASDEX Upgrade discharges, one of which exhibits a pronounced peaking of the ion temperature profile not reproduced by TGLF-ASTRA. We show that GENE-Tango can correctly capture the ion temperature peaking observed in the experiment. By retaining different physical effects in the GENE simulations, e.g., collisions, toroidal rotation and electromagnetic effects, we demonstrate that the ion temperature profile's peaking is due to electromagnetic effects of submarginal (stable) KBM modes. Based on these results, the expected GENE-Tango speedup for the ITER standard scenario is larger than two orders of magnitude compared to a single gyrokinetic simulation up to the transport time scale, possibly making first-principles ITER simulations feasible on current computing resources.

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Section: Electrostatic Gene-tango Simulation With Collisions and Exte...supporting

confidence: 92%

Global gyrokinetic simulations of ASDEX Upgrade up to the transport timescale with GENE–Tango

Siena¹,

Navarro²,

Luda³

et al. 2022

Nucl. Fusion

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“…look into the normalized electron particle flux (corresponding to the values of the last column of the table), observing that only the presence of the E × B shearing non-negligibly changes it, leading to slightly smaller values of T e Γ e /(q e + q i ). This could cause a tiny increase in the density peaking due to E × B shearing for the NBI case as also reported in [29], but as the rotation is relatively small with respect to typical JET Hmode plasmas with only 8 MW of NBI heating (central v tor = 110 km s −1 ), the influence of E × B shearing on the peaking is expected to be small. However, looking into the absolute values of heat fluxes, it is evident that while the E × B shearing only slightly affects T e Γ e /(q e + q i ), its presence reduces the single fluxes by ∼50%.…”

Section: Gyrokinetic and Integrated Transport Modelling Of The Icrh A...mentioning

confidence: 56%

Role of NBI fuelling in contributing to density peaking between the ICRH and NBI identity plasmas on JET

et al. 2022

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Density peaking has been studied between an ICRH and NBI identity plasma in JET. The comparison shows that 8MW of NBI heating/fueling increases the density peaking by a factor of two, being R/Ln=0.45 for the ICRH pulse and R/Ln=0.93 for the NBI one averaged radially over ρtor=0.4‒0.8. The dimensionless profiles of q, ρ*, υ*, βn and Ti/Te≈1 were matched within 5% difference except in the central part of the plasma (ρtor<0.3). The difference in the curvature pinch (same q-profile) and thermo-pinch (Ti=Te) between the ICRH and NBI discharges is virtually zero. Both the gyro-kinetic simulations and integrated modelling strongly support the experimental result where the NBI fuelling is the main contributor to the density peaking for this identity pair. It is to be noted here that the integrated modeling does not reproduce the measured electron density profiles, but approximately reproduces the difference in the density profiles between the ICRH and NBI discharge. Based on these modelling results and the analyses, the differences between the two pulses in impurities, fast ions, toroidal rotation and radiation do not cause any such changes in the background transport that would invalidate the experimental result where the NBI fuelling is the main contributor to the density peaking. This result of R/Ln increasing by a factor of 2 per 8MW of NBI power is valid for the ITG dominated low power H-mode plasmas. However, some of the physics processes influencing particle transport, like rotation, turbulence and fast ion content scale with power, and therefore, the simple scaling on the role of the NBI fuelling in JET is not necessarily the same under higher power conditions or in larger devices.

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“…However, at the lowest collisionality, as might have been expected from the formation of the internal transport barrier, the radial electric field has developed a substantial well, see blue curve on figure 15. Previous experimental observations, closer to the top of the pedestal have indicated that the changes to the radial electric field can have an important impact on particle transport [11][12][13]. This is another indication that the observed changes at the lowest collisionality are beyond a direct effect of the collisionality on the ITG and TEM contributions to the particle flux.…”

Section: Role Of the Radial Electric Fieldmentioning

confidence: 81%

“…The E × B shearing rate is known to be a regulator for turbulence and turbulent transport in plasmas [10]. It has been shown that a sufficiently strong E × B shearing rate can have a significant effect upon particle transport specifically [11][12][13]. It is impossible from the multi-machine database to isolate this effect.…”

Section: Introductionmentioning

confidence: 99%

Collisionality driven turbulent particle transport changes in DIII-D H-mode plasmas

Mordijck

Rhodes²,

Zeng³

et al. 2020

Nucl. Fusion

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The results of the experimental dimensionless scan in this paper confirm that there is an increase in density peaking towards lower collisionality and that this can be partly linked to a shift in the turbulence regime from ITG towards TEM. However at the lowest collisionality, the changes in turbulence and transport are much more pronounced than expected from direct collisionality effect on the turbulence. In this paper, the collisionality, ν * is varied by a factor 5, while keeping ρ * , q, β, M, T e /T i fixed. Additionally, a 3 Hz gas puff modulation is applied to modulate the electron density profile and extract the perturbed transport coefficients using two diagnostics. The transport analysis shows that the increase in density peaking at low ν * is linked to an increase in the inward particle pinch and not an increase in core fueling. These observations are not only in agreement with prior modeling scans of how turbulence changes as a function of collisionality and its impact upon the particle fluxes, but also with the multi-machine database (Fable E. et al 2010 Plasma Phys. Control. Fusion 52 015007) (Angioni C. et al 2003 Phys. Rev. Lett. 90 205003). The changes in turbulence across the collisionality scan were captured at large scale by the BES and at smaller scale by the DBS. A comparison with gradient-driven GENE simulations showed similar trends at both scales. Moreover, the changes observed in overall transport are in agreement with gradient-driven TGLF particle flux simulations. This indicates that TGLF/GENE when given the gradients as input, are able to reproduce the experimentally observed turbulence changes.

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A new mechanism for increasing density peaking in tokamaks: improvement of the inward particle pinch with edge E × B shearing

Cited by 13 publications

References 32 publications

Global gyrokinetic simulations of ASDEX Upgrade up to the transport timescale with GENE–Tango

Global gyrokinetic simulations of ASDEX Upgrade up to the transport timescale with GENE–Tango

Role of NBI fuelling in contributing to density peaking between the ICRH and NBI identity plasmas on JET

Collisionality driven turbulent particle transport changes in DIII-D H-mode plasmas

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