Your search keyword '"Liu, Y.Q."' showing total 7 results

1. Resonant mode effects on rotation braking induced by n  = 1 resonant magnetic perturbations in the EAST tokamak.

Author

Sheng, H., Sun, Y.W., Li, X.Y., Li, H.H., Wu, X.M., Li, Y.Y., Mao, S.F., Ma, Q., Liu, Y.Q., Ye, C., Yan, X.T., Xie, P.C., Zang, Q., Wang, H.H., Jia, M.N., and Ye, M.Y.

Subjects

FUSION reactors, PLASMA oscillations, PLASMA boundary layers, TOKAMAKS, TORQUE, ROTATIONAL motion

Abstract

The spectrum effects on toroidal rotation braking, induced by n = 1 resonant magnetic perturbations (RMPs) in the discharges with q 95 = 4.1 and q 95 = 5.1 , are studied in the EAST tokamak. Here n is the toroidal mode number, RMP spectrum is varied by scanning δ ϕ U L , the phase difference between the upper and lower rows of RMP coils. The toroidal rotation changes periodically with the periodic δ ϕ U L scanning and such an effect is stronger in the discharge with lower q 95 = 4.1. The spectrum dependence of the neoclassical toroidal viscosity (NTV) torque, modeled by NTVTOK based on the magnetic perturbation obtained from MARS-F calculation, agrees well with that of the experimentally observed braking torques in both discharges. The modeled NTV torque is stronger in the discharge with lower q 95, which also agrees with the observations. The comparisons between the spectrum dependence of the NTV and magnetic perturbations show that the resonant mode of magnetic perturbations near the plasma edge mainly contribute the NTV torque. These agreements between modeling and experiments highlight the capability of NTV theory in explaining the experimental observation in the EAST tokamak. [ABSTRACT FROM AUTHOR]

Published

2023

2. Quasi-linear toroidal simulations of resonant magnetic perturbations in eight ITER H-mode scenarios.

Author

Li, L., Liu, Y.Q., Loarte, A., Pinches, S.D., Polevoi, A., Becoulet, M., Huijsmans, G.T.A., and Zhong, F.C.

Subjects

*TOROIDAL plasma, *PLASMA currents, *TOROIDAL magnetic circuits, *PLASMA flow, *PLASMA boundary layers, *SAFETY factor in engineering

Abstract

Both linear and quasi-linear aspects of the plasma response to the resonant magnetic perturbation (RMP) field are numerically investigated for various H-mode scenarios in ITER, covering the pre-fusion power operation and the fusion power operation phases. Linear response computations for eight ITER scenarios, with varying plasma current and toroidal magnetic field, reveal that the best coil current phasing for controlling the type-I edge localized modes (ELMs) scales roughly linearly with the edge safety factor. The coil phasing is defined as the relative toroidal phase of the coil currents between different rows, for a given toroidal harmonic. Quasi-linear initial value simulation, which is the focus of the present study, shows that application of the n = 3 (n is the toroidal mode number) RMP field has a minimum side effect on the plasma core momentum confinement but potentially a large effect on the global particle transport. Generally, the RMP field with the best (worst) coil phasing for ELM control produces the strongest (weakest) effect on the plasma edge flow and the overall density. This robustly holds for all eight ITER scenarios. Consequently, in order to minimize the RMP induced side effects while achieving ELM control (suppression) in ITER, a compromise is necessary in choosing the coil current configuration. [ABSTRACT FROM AUTHOR]

Published

2022

3. Non-linear MHD modelling of edge localized modes suppression by resonant magnetic perturbations in ITER.

Author

Becoulet, M., Huijsmans, G.T.A., Passeron, C., Liu, Y.Q., Evans, T.E., Lao, L.L., Li, L., Loarte, A., Pinches, S.D., Polevoi, A., Hosokawa, M., Kim, S.K., Pamela, S.J.P., Futatani, S., and the JOREK Team

Subjects

TOROIDAL harmonics, THERMAL plasmas, PLASMA flow, HEAT flux, PLASMA boundary layers, PLASMA turbulence, EXTRAPOLATION, MISSING data (Statistics)

Abstract

Edge localized modes (ELMs) suppression by resonant magnetic perturbations (RMPs) was studied with the non-linear magneto-hydro-dynamic (MHD) code JOREK for the ITER H-mode scenarios at 15 MA, 12.5 MA, 10 MA/5.3 T. The main aim of this work was to demonstrate that ELMs can be suppressed by RMPs while the divertor 3D footprints of heat and particle fluxes remain within divertor material limits. The unstable peelingâ€"ballooning modes responsible for ELMs without RMPs were modelled first for each scenario using numerically accessible parameters for ITER. Then the stabilization of ELMs by RMPs was modelled with the same parameters. RMP spectra, optimized by the linear MHD MARS-F code, with main toroidal harmonics N = 2, N = 3, N = 4 have been used as boundary conditions of the computational domain of JOREK, including realistic RMP coils, main plasma, scrape off layer (SOL) divertor and realistic first wall. The model includes all relevant plasma flows: toroidal rotation, two fluid diamagnetic effects and neoclassical poloidal friction. With RMPs, the main toroidal harmonic and the non-linearly coupled harmonics remain dominant at the plasma edge, producing saturated modes and a continuous MHD turbulent transport thereby avoiding ELM crashes in all scenarios considered here. The threshold for ELM suppression was found at a maximum RMP coils current of 45 kAtâ€"60 kAt compared to the coils maximum capability of 90 kAt. In the high beta poloidal steady-state 10 MA/5.3 T scenario, a rotating QH-mode without ELMs was observed even without RMPs. In this scenario with RMPs N = 3, N = 4 at 20 kAt maximum current in RMP coils, similar QH-mode behaviour was observed however with dominant edge harmonic corresponding to the main toroidal number of RMPs. The present MHD modelling was limited in time by few tens of ms after RMPs were switched on until the magnetic energy of the modes saturates. As a consequence the thermal energy was still evolving on this time scale, far from the ITER confinement time scale and hence only the form of 3D footprints on the divertor targets can be indicated within this set-up. Also note, that the divertor physics was missing in this model, so realistic values of fluxes are out of reach in this modelling. However the stationary 3D divertor and particle fluxes could be simply extrapolated from these results to the stationary situation considering that a large power fraction should be radiated in the core and SOL and only about 50 MW power is going to the divertor, which is an arbitrary, but reasonable number used here. The 3D footprints with RMPs show the characteristic splitting with the main RMP toroidal symmetry. The maximum radial extension of the footprints typically was ∼20 cm in inner divertor and ∼40 cm in outer divertor with stationary heat fluxes decreasing further out from the initial strike point from ∼5 MW mâˆ'2 to ∼1 MW mâˆ'2 assuming a total power in the divertor and walls is 50 MW. The heat fluxes remain within the divertor target and baffle areas, however with rather small margin in the outer divertor which could be an issue for the first wall especially in transient regimes when part of the plasma thermal energy is released due to switching on the RMP coils. This fact should be considered when RMPs are applied with a more favorable application before or soon after the Lâ€"H transition, although optimization is required to avoid increasing the Lâ€"H power threshold with RMPs. [ABSTRACT FROM AUTHOR]

Published

2022

4. Toward holistic understanding of the ITER-like resonant magnetic perturbation (RMP) ELM control on KSTAR.

Author

In, Yongkyoon, Lee, H.H., Park, G.Y., Jeon, Y.M., Kim, M., Kim, K., Park, J.-K., Yang, S.M., Loarte, A., Liu, Y.Q., Park, H., and the 3D Physics Task Force in KSTAR

Subjects

HEAT flux, PLASMA boundary layers, HEATING control

Abstract

KSTAR has clarified a set of unresolved 3D physics issues utilizing the ITER-like in-vessel, three-row, resonant magnetic perturbation (RMP) configurations. Since RMP-driven, edge-localized-modes (ELMs)-crash control elevates the divertor heat flux peak through its impact on edge plasma parameters and transport, a series of intentionally misaligned RMP configurations (IMCs) have been explored to investigate the relationship between RMP ELM control and divertor heat fluxes, while searching for an ideal IMC that could be favorable in both aspects. First of all, the contrasting influence of kink vs anti-kink phasing on the ELM-crash suppression has been articulated, demonstrating the synergistic benefit of ‘kink’ phasing on ELM-crash-suppression. On the other hand, the three-row IMC in the anti-kink phasing becomes more insensitive to the ELM-crashes at the sub-marginal level of RMP, consistent with theory. Meanwhile, the divertor ‘wetted’ area of ELM-crash-suppression gets narrower than that of ELM-crash-mitigation, suggesting that ELM-crash-mitigation remains advantageous over ELM-crash-suppression in terms of time-averaged divertor thermal loading. In comparison, based on a set of two-row IMCs, no evidence of divertor heat flux broadening was found during ELM-crash-suppression, supporting a hypothesis that the dispersal of the divertor heat flux in three-row IMCs cannot be driven by helically structured two-row RMPs alone. Among ITER-like three-rows, lower two-row RMPs have been found to be much more effective in suppressing the ELM-crashes than upper two-row RMPs. Although it is quite preliminary, the up/down asymmetric dependence of RMP coupling may be generically attributed to lower-single-null plasmas. Such a holistic understanding of RMP-driven, ELM-crash-control in KSTAR is expected not only to elucidate various subtle points in the vicinity of ELM-crash-suppression, but also to clarify the relevant divertor thermal loading issues for ITER and beyond. [ABSTRACT FROM AUTHOR]

Published

2022

5. MARS-Q modeling of kink-peeling instabilities in DIII-D QH-mode plasma.

Author

Dong, G.Q., Liu, Y.Q., Chen, X., Hao, G.Z., Liu, Y., Wang, S., Zhang, N., and Xia, G.L.

Subjects

*SHEAR flow, *HARMONIC oscillators, *POLOIDAL magnetic fields, *PLASMA flow, *PLASMA boundary layers, *PLASMA density, *TOROIDAL plasma

Abstract

In quiescent H-mode (QH-mode) regime, edge harmonic oscillations (EHOs) are believed to provide necessary radial transport to prevent occurrence of large edge localized modes. A systematic modeling study is performed here on the low-n EHOs in a DIII-D QH-mode plasma (Chen et al 2016 Nucl. Fusion 56 076011), by utilizing the MARS-Q code (Liu et al 2013 Phys. Plasmas 20 042503). Both the n = 1 and n = 2 instabilities are found to be strongly localized near the plasma edge, exhibiting the edge-peeling characteristics. The DIII-D resistive wall is found to have minor effects on these instabilities. The plasma resistivity is found to strongly modify the mode growth rate. Assuming the Spitzer model for the plasma resistivity, the computed mode growth rate scales as S−1/3 with S being the Lundquist number. Toroidal flow of the plasma slightly stabilizes these edge localized kink-peeling modes. Drift kinetic effects all have a destabilization effect on these modes. Non-perturbative magneto-hydrodynamic-kinetic hybrid computations find that the drift kinetic effects associated with thermal particle species push the peak location of the eigenmode radially inward but still in the pedestal region. The modeled plasma temperature and density fluctuations in the plasma edge region, as well as the poloidal magnetic field perturbations along both the low and high field sides of the plasma surface, are in good agreement with experimental measurements. Finally, the quasi-linear initial value simulations find a strong non-linear interplay between the kink-peeling instability and the toroidal flow near the plasma edge. The combined effect of the damping of the flow amplitude and change of the edge flow shear is found to be the stabilizing factor for the kink-peeling mode, leading to the mode saturation and thus EHOs. [ABSTRACT FROM AUTHOR]

Published

2021

6. Optimizing beam-ion confinement in ITER by adjusting the toroidal phase of the 3D magnetic fields applied for ELM control.

Author

Sanchis, L., Garcia-Munoz, M., Viezzer, E., Loarte, A., Li, L., Liu, Y.Q., Snicker, A., Chen, L., Zonca, F., Pinches, S.D., and Zarzoso, D.

Subjects

MAGNETIC fields, NEUTRAL beams, TOROIDAL plasma, PLASMA boundary layers, PLASMA resonance, DISTRIBUTION (Probability theory)

Abstract

The confinement of neutral beam injection (NBI) particles in the presence of n = 3 resonant magnetic perturbations (RMPs) in 15 MA ITER DT plasmas has been studied using full orbit ASCOT simulations. Realistic NBI distribution functions, and 3D wall and equilibria, including the plasma response to the externally applied 3D fields calculated with MARS-F, have been employed. The observed total fast-ion losses depend on the poloidal spectra of the applied n = 3 RMP as well as on the absolute toroidal phase of the applied perturbation with respect to the NBI birth distribution. The absolute toroidal phase of the RMP perturbation does not affect the ELM control capabilities, which makes it a key parameter in the confinement optimization. The physics mechanisms underlying the observed fast-ion losses induced by the applied 3D fields have been studied in terms of the variation of the particle canonical angular momentum (δPϕ) induced by the applied 3D fields. The presented simulations indicate that the transport is located in an edge resonant transport layer as observed previously in ASDEX upgrade studies. Similarly, our results indicate that an overlapping of several linear and nonlinear resonances at the edge of the plasma might be responsible for the observed fast-ion losses. The results presented here may help to optimize the RMP configuration with respect to the NBI confinement in future ITER discharges. [ABSTRACT FROM AUTHOR]

Published

2021

7. Design, installation and operation of in-vessel resonant magnetic perturbation system on the HL-2A tokamak.

Author

Sun, T.F., Ji, X.Q., Liu, Yi, Liu, Y.Q., Li, Xu, Liang, S.Y., Lu, P., Zhang, J.Z., and Xu, Yuan

Subjects

*FREQUENCY changers, *POWER resources, *MAGNETIC fields, *PROTHROMBIN, *PLASMA boundary layers

Abstract

• An set of in-vessel RMP coil system with 2 × 2 array has been installed in HL-2A. • A high-frequency switching PS based on H-bridge controlled by IGBT powers coils. • ELM mitigation has been realized by the compacted RMP system on HL-2A. H-mode discharges with edge localized modes (ELMs) have been achieved in the HL-2A tokamak with combined auxiliary heating of NBI and ECRH. In order to realize the mitigation or suppression of ELMs in HL-2A plasmas and also to explore the ELM suppression and other 3D magnetic field physics, a set of compact in-vessel resonant magnetic perturbation (RMP) coils (2×2 array) has been recently designed and installed on the HL-2A tokamak to meet the limited space requirement. There are two rows of coils (upper and lower separated poloidally 66.5°), with each row consisting of 2 coils separated from each other by 180° along the toroidal direction. Each coil spans about 11.4° toroidally. Meanwhile, an integral solid-state regulating power supply system with a high switching frequency and an AC–DC–AC converter configuration has been designed and fabricated for the RMP system. It can provide DC and AC with various waveforms. The maximum amplitude of DC is 5.0 kA and the frequency of AC can reach 3 kHz. These in-vessel coils can produce sufficient RMPs in the plasma edge during typical HL-2A H-mode discharges. The ELM mitigation by applying an n = 1 RMP has been observed in recent HL-2A experiments. The ELM frequency was increased by a factor of 2 and the amplitude of the D α emission decreased, leading to a reduced heat load on the divertor plates. [ABSTRACT FROM AUTHOR]

Published

2019