Experimental evidence of the non-local response of transport to peripheral perturbations

Sun, H. J.; Diamond, P. H.; Shi, Z.B.; Chen, C.Y.; Lianghua, Yao; Ding, X.T.; Feng, B.B.; Huang, Xianli; Zhou, Yan; Zhou, J.; Song, X.M.

doi:10.1088/0029-5515/51/11/113010

Cited by 18 publications

(35 citation statements)

References 34 publications

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“…The plasma current (I p ) and edge safety factor (q a ) are 150kA and about 3.7, respectively. The typical NLT effect in electron heat transport channel (core T e rises while edge T e drops) appears in every SMBI pulse, which is same as previous NLT experiments in other devices [1][2][3][4][5][6][7][8][9][10][11][12]. On the other hand, the prompt increasing of core ion temperature and rapid decreases of edge T i due to SMBI are also clearly shown in fig.1.…”

supporting

confidence: 85%

“…A fast increase of the central electron temperature caused by the edge cooling in Ohmic heating (OH) plasmas, the so-called non-local heat transport (NLT) [1] is one of these challenging issues. NLT was first observed in the TEXT tokamak 23 years ago, and in many fusion devices afterwards (TFTR [2], RTP [3], ASDEX UPGRAGE [4], Tore Supra [5], JET [6], LHD [7][8][9], HL-2A [10][11][12], Alcator C-Mod [13][14][15], KSTAR [16], J-TEXT [17], and EAST [18]). NLT phenomenon shows that the limitation of transport theory based on traditional local transport model.…”

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confidence: 99%

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Observation of non-local effects in ion transport channel in J-TEXT plasmas

et al. 2020

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In cold pulse experiments in J-TEXT, the ion transport shows similar non-local response as the electron transport channel. Very fast ion temperatures decreases are observed in the edge, while the ion temperature in core promptly begin to rise after the injection of cold pulse. Moreover, the cutoff density is also found for the ion non-local effect. The experimental observed density fluctuation in a high frequency ranging from 500 kHz to 2 MHz is obviously reduced in the whole plasma region during non-local transport (NLT) phase.

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confidence: 85%

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confidence: 99%

Observation of non-local effects in ion transport channel in J-TEXT plasmas

et al. 2020

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“…In particular, the finding that avalanches exhibit long correlation lengths suggests a natural explanation for nonlocal heat transport, observed in the studies of response to localized perturbations. 54,55 Heat transport in ITBs is related to momentum transport, as elucidated in recent experimental 56 and simulation 35,57 studies. Recent gyrokinetic simulations also show the close connection between heat and momentum avalanches in Lmode, showing cross PDFs by which outward heat avalanches induce inward momentum avalanches.…”

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confidence: 99%

A statistical analysis of avalanching heat transport in stationary enhanced core confinement regimes

et al. 2012

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We present a statistical analysis of heat transport in stationary enhanced confinement regimes obtained from flux-driven gyrofluid simulations. The probability density functions of heat flux in improved confinement regimes, characterized by the Nusselt number, show significant deviation from Gaussian, with a markedly fat tail, implying the existence of heat avalanches. Two types of avalanching transport are found to be relevant to stationary states, depending on the degree of turbulence suppression. In the weakly suppressed regime, heat avalanches occur in the form of quasiperiodic (QP) heat pulses. Collisional relaxation of zonal flow is likely to be the origin of these QP heat pulses. This phenomenon is similar to transient limit cycle oscillations observed prior to edge pedestal formation in recent experiments. On the other hand, a spectral analysis of heat flux in the strongly suppressed regime shows the emergence of a 1/f (f is the frequency) band, suggesting the presence of self-organized criticality (SOC)-like episodic heat avalanches. This episodic 1/f heat avalanches have a long temporal correlation and constitute the dominant transport process in this regime. V

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“…(II) The sign of the perturbation reverses, i.e., a cooling at the edge results in heating of the core, and vice versa. Such evidence has accumulated through dedicated experiments, including edge cooling by laser blowoff (LBO) of impurities, pellets, radio frequency (RF) heating, and plasma current ramping, performed in several devices, including tokamaks and stellarators [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19]. The ubiquity of these phenomena calls naturally for some common fundamental physics basis.…”

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confidence: 99%

Alfvénic Propagation: A Key to Nonlocal Effects in Magnetized Plasmas

Sattin¹,

Escande

2014

Phys. Rev. Lett.

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A long-standing puzzle in fusion research comes from experiments where a sudden peripheral electron temperature perturbation is accompanied by an almost simultaneous opposite change in central temperature, in a way incompatible with local transport models. This Letter shows that these experiments and similar ones are fairly well quantitatively reproduced, when induction effects are incorporated in the total plasma response, alongside standard local diffusive transport, as suggested in earlier work [Plasma Phys. Controlled Fusion 54, 124036 (2012).

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Experimental evidence of the non-local response of transport to peripheral perturbations

Cited by 18 publications

References 34 publications

Observation of non-local effects in ion transport channel in J-TEXT plasmas

Observation of non-local effects in ion transport channel in J-TEXT plasmas

A statistical analysis of avalanching heat transport in stationary enhanced core confinement regimes

Alfvénic Propagation: A Key to Nonlocal Effects in Magnetized Plasmas

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