Self-driven current generation in turbulent fusion plasmas

Wang, W.X.; Hahm, T.S.; Startsev, Edward A.; Ethier, S.; Chen, J.; Yoo, Min-Gu; Ma, Chenhao

doi:10.1088/1741-4326/ab266d

Cited by 15 publications

(25 citation statements)

References 32 publications

(48 reference statements)

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“…5 The current driven by turbulence has been discussed in detail using the analytical and numerical approaches. 3,4,[6][7][8][9][10] It has been shown by S. -I. Itoh and K. Itoh firstly with a slab model. 6 Driftwave fluctuations drive a net current when k is finite, where k is the averaged parallel wave number over the spectrum .…”

Section: Introductionmentioning

confidence: 93%

“…The spontaneous variation of electron momentum provides a current source which corrugates the current density profile and has significant impacts on the generation of the plasma self-driven mean current. 3,4 The current induced by turbulence affects the MHD instabilities which can provide a way to study the interaction between the turbulence and the MHD instabilities.…”

Section: Introductionmentioning

confidence: 99%

“…A direct calculation of electron and ion current generation by ITG and CTEM turbulence was reported in early global the turbulence acceleration is discussed by Wang. 4 The electrostatic studies by Yi 9 show that the net current induced by electron temperature gradient turbulence is approximately 20% of the local bootstrap current density. Most previous simulations of the current flow generation in tokamak plasmas are based on the long wave-length approximation in the quasi-neutrality equation, and the fine structures of the turbulence driven current have not been thoroughly investigated.…”

Section: Introductionmentioning

confidence: 99%

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Gyrokinetic simulations of electric current generation in ion temperature gradient driven turbulence

Chen,

Lu,

Cai

et al. 2021

Preprint

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Gyrokinetic simulations in the collisionless limit demonstrate the physical mechanisms and the amplitude of the current driven by turbulence. Simulation results show the spatio-temporal variation of the turbulence driven current and its connection to the divergence of the Reynolds stress and the turbulence acceleration. Fine structures (a few ion Larmor radii) of the turbulence induced current are observed near the rational surfaces with the arbitrary wavelength solver of the quasi-neutrality equation. The divergence of the Reynolds stress plays a major role in the generation of these fine structures. The so-called "spontaneous" current is featured with large local magnitude near the rational surfaces.

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Section: Introductionmentioning

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Gyrokinetic simulations of electric current generation in ion temperature gradient driven turbulence

Chen,

Lu,

Cai

et al. 2021

Preprint

View full text Add to dashboard Cite

show abstract

“…For decades since the invention of the tokamak, various external or self-generated current drive mechanisms have been developed for steady-state operations, such as radio frequency-driven, neutral beam injection (NBI)-driven, and bootstrap current. Recently, it was found that micro-instabilities can also generate or modify the plasma current 1 – 4 , which could probably explain an anomaly in the current profile found in experiments such as in the hybrid operation scenario 5 . The self-generated current drive mechanisms have been predicted in theories 1 , 2 , 4 , 6 , then discovered in experiments 7 – 9 and they were found to be consistent with each other.…”

Section: Introductionmentioning

confidence: 99%

“…Recently, it was found that micro-instabilities can also generate or modify the plasma current 1 – 4 , which could probably explain an anomaly in the current profile found in experiments such as in the hybrid operation scenario 5 . The self-generated current drive mechanisms have been predicted in theories 1 , 2 , 4 , 6 , then discovered in experiments 7 – 9 and they were found to be consistent with each other.…”

Section: Introductionmentioning

confidence: 99%

Observation of a new type of self-generated current in magnetized plasmas

Seo

Lee

et al. 2022

Nat Commun

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A tokamak, a torus-shaped nuclear fusion device, needs an electric current in the plasma to produce magnetic field in the poloidal direction for confining fusion plasmas. Plasma current is conventionally generated by electromagnetic induction. However, for a steady-state fusion reactor, minimizing the inductive current is essential to extend the tokamak operating duration. Several non-inductive current drive schemes have been developed for steady-state operations such as radio-frequency waves and neutral beams. However, commercial reactors require minimal use of these external sources to maximize the fusion gain, Q, the ratio of the fusion power to the external power. Apart from these external current drives, a self-generated current, so-called bootstrap current, was predicted theoretically and demonstrated experimentally. Here, we reveal another self-generated current that can exist in a tokamak and this has not yet been discussed by present theories. We report conclusive experimental evidence of this self-generated current observed in the KSTAR tokamak.

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Advanced operation modes relying on core plasma turbulence stabilization in tokamak fusion devices

2023

AAPPS Bull.

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Recent progress of advanced operation modes in tokamaks is addressed focusing upon internal transport barrier (ITB) discharges. These ITB discharges are being considered as one of candidate operation modes in fusion reactors. Here, “internal” means core region of a fusion plasma, and “transport barrier” implies bifurcation of transport phenomena due to suppressing plasma turbulence. Although ITB discharges have been developed since the mid-1990, they have been suffering from harmful plasma instabilities, impurity accumulation, difficulty of feedback control of kinetic plasma profiles such as pressure or current density, and so on. Sustainment of these discharges in long-pulse operations above wall saturation time is another huddle. Recent advances in ITB experiments to overcome the difficulties of ITB discharges are addressed for high βp plasmas in DIII-D, broad ITB without internal kink mode in HL-2A, F-ATB (fast ion-induced anomalous transport barrier) in ASDEX upgrade, ion and electron ITB in LHD, and FIRE (fast ion regulated enhancement) mode in KSTAR. The core-edge integration is discussed in the ITB discharges. The DIII-D high βp plasmas facilitate divertor detachment which weakens the edge transport barrier (ETB) but extends the ITB radius resulting in a net gain in energy confinement. Double transport barriers were observed in KSTAR without edge localized mode (ELM). FIRE modes in KSTAR are equipped with the I-mode-like edge which prevents the ELM burst and raise the fusion performance together with ITB. Finally, long sustainment of ITBs is discussed. EAST established electron ITB mode in long-pulse operations. JET achieved quasi-stationary ITB with active control of the pressure profile. JT-60U obtained 28 s of high βp hybrid mode, and KSTAR sustained stable ITB in conventional ITB mode as well as FIRE mode. These recent outstanding achievements can promise ITB scenarios as a strong candidate for fusion reactors.

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Self-driven current generation in turbulent fusion plasmas

Cited by 15 publications

References 32 publications

Gyrokinetic simulations of electric current generation in ion temperature gradient driven turbulence

Gyrokinetic simulations of electric current generation in ion temperature gradient driven turbulence

Observation of a new type of self-generated current in magnetized plasmas

Advanced operation modes relying on core plasma turbulence stabilization in tokamak fusion devices

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