Effects of sawtooth heat pulses on edge flows and turbulence in a tokamak plasma

2023-03-09 05:45KaijunZHAO赵开君YoshihikoNAGASHIMAZhibinGUO郭志彬PatrickDIAMONDJiaqiDONG董家齐LongwenYAN严龙文KimitakaITOHSanaeITOHXiaoboLI李晓博JiquanLI李继全AkihideFUJISAWAShigeruINAGAKIJunCHENG程钧JianqiangXU许健强YusukeKOSUGAMakotoSASAKIZhengxiongWA
Plasma Science and Technology 2023年1期
关键词:龙文

Kaijun ZHAO(赵开君),Yoshihiko NAGASHIMA,Zhibin GUO(郭志彬),Patrick H DIAMOND,Jiaqi DONG(董家齐),Longwen YAN(严龙文),Kimitaka ITOH,Sanae-I ITOH,7,9,†,Xiaobo LI(李晓博),Jiquan LI(李继全),Akihide FUJISAWA,Shigeru INAGAKI,Jun CHENG(程钧),Jianqiang XU(许健强),Yusuke KOSUGA,Makoto SASAKI,Zhengxiong WANG(王正汹),Huaiqiang ZHANG(张怀强),Yuqian CHEN(陈俞钱),Xiaogang CAO(曹小岗),Deliang YU(余德良),Yi LIU(刘仪),Xianming SONG(宋显明),Fan XIA(夏凡) and Shuo WANG(王硕)

1 School of Nuclear Science and Engineer,East China University of Technology,Nanchang 330013,People’s Republic of China

2 Research Institute for Applied Mechanics,Kyushu University,Kasuga 816-8580,Japan

3 School of Physics,Peking University,Beijing 100871,People’s Republic of China

4 Center for Momentum Transport and Flow Organization,University of California at San Diego,California 92093,United States of America

5 Southwestern Institute of Physics,Chengdu 610041,People’s Republic of China

6 Institute of Science and Technology Research,Chubu University,Aichi 487-8501,Japan

7 Research Center for Plasma Turbulence,Kyushu University,Kasuga 816-8580,Japan

8 National Institute for Fusion Science,Toki 509-5292,Japan

9 Department of Innovative Energy Science and Engineering,Graduate School of Engineering,Chubu University,Aichi 487-8501,Japan

10 Institute of Fusion Science,School of Physical Science and Technology,Southwest Jiaotong University,Chengdu 610031,People’s Republic of China

11 School of Physics and Optoelectronic Technology,Dalian University of Technology,Dalian 116024,People’s Republic of China

Abstract Enhancements of edge zonal flows,radial electric fields,and turbulence are observed in electron cyclotron resonance heating-heated plasmas(Zhao et al 2013 Nucl.Fusion 53 083011).In this paper,the effects of sawtooth heat pulses on flows and turbulence are presented.These experiments are performed using multiple Langmuir probe arrays in the edge plasmas of the HL-2A tokamak.The edge zonal flows,radial electric fields,and turbulence are all enhanced by sawteeth.Propagation of the zonal flow and turbulence intensities is also observed.The delay time of the maximal intensity of the electric fields,zonal flows,and turbulence with respect to the sawtooth crashes is estimated as∼1 ms and comparable to that of the sawtooth-triggered intermediate phases.Not only the zonal flows but also the radial electric fields lag behind the turbulence.Furthermore,the intensities of both the zonal flows and electric fields nearly linearly increase/decrease with the increase/decrease of the turbulence intensity.A double-source predator–prey model analysis suggests that a relatively strong turbulence source may contribute to the dominant zonal flow formation during sawtooth cycles.

Keywords:tokamak,Langmuir probe arrays,edge flows and turbulence,sawtooth heat pulses

1.Introduction

Sawtooth,a nonlinear oscillation phenomenon in core plasmas of tokamaks,is an active research area in the fusion field since it has been observed on ST tokamak[1].The study of the effects of sawtooth heat pulses on flows and turbulence aims to understand and control plasma confinement and transport.Presently,it is an urgent task to the lower power threshold to access high-confinement mode(H-mode)for ITER.The confinement regime transitions can be triggered by sawtooth heat pulses experimentally[2–5].Sawteeth may offer a way to access H-modes if their deleterious effects can be mitigated.As the sawtooth heat pulse propagates to edge plasmas,the edge flows and turbulence will be varied significantly[6].Some deleterious instabilities,such as neoclassical tearing modes,can also be induced by large sawteeth[7,8].

The sawtooth,sometimes called internal disruption,can lead to repetitive density pulse,heat pulse,and turbulence clump propagations from core to edge plasmas.Thus,the properties of turbulence and transport during benign disruption have attracted much more attention in recent years.The measurement of heat pulses due to sawtooth instability shows that the heat diffusivity is significantly larger than that from power balance analysis[9].The identification of the causal relationship between heat fluxes and local temperature gradients suggests that ballistic heat transport exists during sawtooth cycles[10].

The sawtooth oscillation can change flows via changing edge density,temperature,gradient,and turbulence.It is well recognized thatE×Bsheared flows play important roles in confinement regime transitions in high-temperature plasmas.Generally,such flows exist in the forms of zonal flows selfgenerated by turbulence and mean flows driven by ion pressure gradients[11–20].Two kinds of zonal flows(i.e.,lowfrequency zonal flows(LFZFs)[11–17]and geodesic acoustic modes(GAMs)[19–22])are found in toroidal plasmas.The increases in turbulence levels due to sawteeth were observed using Langmuir probe(LP)arrays[6,23]and by CO2laser forward scattering[24].The GAM was observed to be reduced significantly by sawteeth[6].The fluctuation-driven particle and heat fluxes can be enhanced due to sawtooth crashes in the edge plasmas[23].However,sawtooth effects on the LFZFs and the time delay of turbulence with respect to sawtooth crashes have not been observed experimentally.

Slowly increasing heating power near the H-mode power threshold,an intermediate,quasi-periodic state,called I-phase,dithering H-mode,or a limit-cycle oscillation was detected.In the I-phase,turbulence,zonal,and mean flows all couple with the pressure gradient.Extensive studies of the I-phases suggest that the flow–turbulence interaction contributes to H-mode triggering[25].The I-phase is quite distinct from the I-mode operating regime on the Alcator C-Mod tokamak that is a steady-state regime[26].The I-phase can be triggered by sawtooth heat pulses[3].

Here,the enhancement of the edge zonal flows,radial electric fields,and turbulence during sawtooth cycles is presented.The estimated delay time of the edge flows and turbulence with respect to sawtooth crashes is ∼1 ms in lowconfinement mode(L-mode)plasmas and comparable to the evaluation of that of L–I transitions.Double-source predator–prey model analysis suggests that the dominant zonal flows could be driven by the relatively strong turbulence burst propagation during sawtooth cycles.

The rest of this work is organized as follows.The experimental setup is given in section 2.The experimental results,described in section 3,include the sawtooth propagation,sawtooth modulation on turbulence and flows,conditional average analyses of the edge flows and turbulence,trajectories of turbulence and flows,analysis of a doublesource predator–prey model,the radial structure of the LFZF and turbulence,and sawtooth-triggered I-phases.Section 4 presents the conclusion and discussion.

2.Experimental setup

Experiments were performed in deuterium plasmas on the HL-2A tokamak with limiter and diverter configurations.The major radius of the HL-2A tokamak isR=1.65 m,and its minor radii area=0.4 m(limiter discharge)and 0.38 cm(diverter discharge).The limiter is at the outer midplane.First,the zonal flows,radial electric fields,and turbulence relating to sawtooth crashes are measured in electron cyclotron resonance heating(ECRH)-heated plasmas with limiter configuration.The on-axis ECRH is used,and its power ∼500 kW far below the power threshold of L–H transitions is inputted.The plasma parameters are the toroidal magnetic fieldBt=1.2–1.3 T,the plasma currentIp=150–180 kA,the line-averaged electron densityNe=(1–2)×1019m−3,and the safety factorqa=3.3.Multiple LP arrays were used to measure floating potential fluctuations,as shown in figures 1(a)and(b).An LP array of three tips and a four-tip LP array form a fast reciprocating probe set of seven tips with poloidal span of 65 mm.A radial rake probe array of 12 tips is located in the poloidal cross section ∼2100 mm away from the set of seven tips toroidally.Next,the flows and turbulence are detected following sawtooth crashes and prior to I-phases in diverter discharge with neutral-beam injection(NBI)of∼1 MW.The NBI power is close to,but still below,the threshold of the L–H transition.The line-averaged electron density(the safety factor)isNe=(2–3)×1019m−3(q95=4.0).The toroidal magnetic field and plasma current are the same as those with limiter discharges.Here,the LP arrays were changed,and a fast reciprocating probe array with two steps and 12 tips was used to yield floating potential,temperature,density,and Mach number[27,28],as shown in figure 1(c).All the LP arrays were mounted on the middle plane outside of the machine.The length and diameters of all the tips are 3 and 2 mm,respectively[29,30].The sampling rate of the probe data is 1 MHz corresponding to Nyquist frequency of 500 kHz.A multiple-channel soft x-ray system is applied to observe the sawtooth oscillations.The viewing chords are vertical,and the radial positions of the chord centers can be evaluated by the Equilibrium and reconstruction FITting(EFIT)code.A single-channelHαarray that views crossing the core plasmas from the low- to high-field side at the midplane is utilized to monitor the edge region.A single-channel array means that there is a photomultiplier tube.Figures 2(a)and(b)show the magnetohydrodynamic equilibrium configurations reconstructed by the EFIT code in limited and diverted plasmas,respectively.

Figure 1.Layout and structure of the LP arrays:(a)plasma column,and probe arrays in(b)limiter and(c)diverter configurations.

Figure 2.Equilibrium reconstructions:(a)limiter and(b)diverter.

3.Experiment results

3.1.Sawtooth propagation

The sawtooth propagation is an important feature due to its relevance to not only the core plasmas but also to the edge plasma parameters.Figures 3(a)–(d)show soft x-ray signals at various positions in the ECRH heating plasmas.The sawtooth crash starts at ∼602.4 ms at the position ofr∼2.5 cm and sharply drops to the minimum value.However,a rapid increase in the intensity of the soft x-ray atr∼16.3 cm appears and propagates to the edge after the sawtooth crash.The significant difference of the sawtooth signals atr∼2.5 and 16.3 cm comes from their positions(i.e.,inside and outside of theq=1 surface).Theq=1 surface is roughly evaluated as ∼15 cm from the measurements of the soft x-ray signals.The propagation time of the sawtooth heat pulses fromr∼16.3 cm tor∼26.9 cm is by about 0.9±0.1 ms,and the corresponding propagation velocity is estimated as∼130 m s−1.

Figure 3.(a)–(d)Soft x-ray signals at various positions in the ECRHheated plasmas.

Figure 4.(a)–(g)Conditional average of gradients of soft x-ray signals at various positions in ECRH-heated plasmas(the last-closed flux surface(LCFS)is located in r=40 cm).

Figure 5.(a)Soft x-ray signals at r∼2.5 cm,(b)floating potential at r∼37 cm,(c)turbulence intensity,and(d)radial electric fields at r∼35.7 cm in the ECRH-heated plasmas(the LCFS is located in r=40 cm).

Sawtooth crashes have significant effects on the temperature,density,and pressure gradient.Figure 4 shows the conditional average of the gradients of the soft x-ray signals at various positions.The conditional average is often utilized to detect the coherent mode signals.Normally,this method requires a reference signal.In this case,the sawtooth crash is considered as a reference signal and calculated by the time derivative of the soft x-ray signals.Near the maximum of the derivative,td=0 is defined,then the data fromtd=−2.5 ms(before the sawtooth crash)to 2.5 ms(after the sawtooth crash)are selected for each sawtooth crash.Here,a total of 20 sawtooth crashes are averaged.The radial distribution of the gradient of the soft x-rays is similar to that of their intensities,that is,the gradient decreases(increases)inside(outside)of theq=1 surface.The propagation time of the gradient fromr=18.25 cm to 28.25 cm is evaluated as ∼0.9±0.1 ms,and its velocity is calculated as ∼130 m s−1.The intensity of the soft x-rays is associated with density and temperature.Note that the soft x-ray intensity also depends on the presence of impurities,although the correlation between impurities and soft x-ray intensity is beyond our discussion in this paper.This result suggests that the gradient propagates during sawtooth cycles.

3.2.Sawtooth modulation on turbulence and flows

As the sawtooth heat pulse propagates to the edge plasmas,the turbulence,zonal flow,and radial electric fields are modulated in the ECRH-heated plasmas.Figures 5(a)–(d)present the soft x-ray signals atr∼2.5 cm,floating potentials atr∼37 cm,the intensity of the turbulence in the frequency bands of 20–200 kHz,and the radial electric fieldsEratr∼35.7 cm,respectively.Both turbulence and radial electric fields are well correlated with the sawteeth.After sawtooth crashes,the intensity of the turbulence increases andErdrops rapidly.Considering that the change of the electron temperature is small at the radial separation of 4 mm,theEris roughly evaluated from the floating potentials at two radial positionsanddrare the potential fluctuations and the radial distance,respectively).

The observation suggests that the sawteeth propagate to the edge and significantly impact the edge turbulence and flows.Usually,in the HL-2A,the width of the scrape-off l ayer isλTe=2–6 cmfor theL-mode plasmas,and the pedestal widthis ∼3 cmfortheH-mode plasmas.

Figure 6 shows the auto-power spectra of potentials less than 100 kHz from 582 to 612 ms at two positions ofr=37 and 37.4 cm.In this analysis,fast Fourier transform is used,and the component at the frequency of ∼0.2 kHz is filtered out to remove the sawtooth oscillations in the floating potential fluctuations.A large power fraction in the frequency region of 0–3 kHz is the LFZF.A sharp peak of ∼10.5 kHz is identified as a mesoscale electric fluctuation(MSEF),which has dominant GAMs andm/n=6/2 components[30,31].The MSEF results from the nonlinear synchronization of the GAMs and magnetic fluctuations.Themandnare the poloidal and toroidal mode numbers,respectively.The LFZFs and GAMs are detected by long-range correlations using potential fluctuations measured simultaneously using Langmuir A and B probe arrays with a toroidal angle of 60°,as seen in figure 1(a).Then=0 for both the LFZFs and GAMs are directly evaluated from the floating potentials with the toroidally distributed probe arrays.Combining potentials with Mirnov signals from magnetic coils set up in the vessel wall,them/n=6/2 component can also be identified at the MSEF frequency.Except for the tearing mode ofm/n=6/2,no significant oscillation in the LFZF and MSEF frequency bands is observed from the Mirnov signal.The feature at∼60 kHz is ambient turbulence.The ion–ion collision frequency is estimated as2.0 ×104s−1.The radial width of the LFZFs is usually about 1–2 cm in the HL-2A,and we are not sure that the sawteeth can affect this width in the present stage.

Figure 6.Auto-power spectra of the floating potential fluctuations less than 100 kHz at two radial positions in the ECRH-heated plasmas.

It is reasonable to imagine that turbulence-driven zonal flows are modulated by sawteeth via varying turbulence.Figures 7(a)–(b)present the soft x-ray signals atr∼2.5 cm and the spectrograms of potential fluctuations in the frequency less than 15 kHz atr∼35.7 cm,respectively.Following sawtooth crashes,the intensity of the LFZFs less than∼3 kHz increases,while that of the MSEFs at the frequency of ∼10.5 kHz decreases.In contrast,before sawtooth crashes,the former decreases,while the latter increases.The phase between LFZFs and MSEFs during sawtooth cycles cannot be explained in the present stage.The summed powers of the turbulence in the frequency bands of 20–200 kHz and the LFZFs are given in figures 6(c)and(d),respectively.The sawtooth modulations on the turbulence and the LFZFs are clearly shown.Note that the observation does not depend on the selection of the time window of the data.

Figure 7.(a)Soft x-ray signals,(b)spectrogram of the floating potential fluctuations,(c)turbulence amplitude,and(d)LFZF amplitudes in the ECRH-heated plasmas.

Figure 8.Conditional average of(a)soft x-ray signals,(b)turbulence intensity,(c)LFZF intensity,(d) Er intensity,and(e)Hα signals in L-mode plasmas with ECRH power ∼500 kW.

3.3.Conditional average analyses of the edge flows and turbulence

The delay time of the edge flows and turbulence with respect to sawtooth crashes in L-mode plasmas is an important parameter to understand the sawtooth propagation and confinement regime transitions.The conditional average method is utilized to estimate the delay time.Figures 8(a)–(d)show the conditional average of the soft x-ray signals atr∼2.5 cm,intensities of turbulence in the frequency band of 20–200 kHz,LFZF in the frequency bands of 0.5–3 kHz,and radial electric fieldsErin the ECRH-heated plasmas,respectively.Before sawtooth crashes,the intensities of the turbulence,Er,and LFZFs slowly decrease,while following sawtooth crashes,they all increase rapidly.Their growth time is roughly ∼1.0 ms,while their decay time is ∼4.0 ms and much longer than their growth time.The LFZFs andErlag behind turbulence,and the intensity of the LFZFs(Er)increases faster fromtd∼0.2 to 1.2 ms(1.0 ms).The delay times of the maxima of the LFZF,Er,and turbulence intensities with respect to sawtooth crashes are ∼1.2±0.2,1.0±0.2,and 0.80±0.2 ms,respectively.The discrepancy of the delay times for the LFZF,Er,and turbulence may come from the difference in their driving mechanisms.Compared with the soft x-ray signals,it seems that turbulence intensity propagation is faster than that of the heat pulses.The delay time ∼0.4 ms of LFZFs with respect to the turbulence is longer than the turbulence decorrelation time or energy transfer time between LFZFs and turbulence.The possible reason is that the critical value of the turbulence intensity is needed for the zonal flow driving,and this will be discussed next.In addition,the intensity of the turbulence(Er)rises up by 50%(30%).For the LFZF,its intensity is increased by 100%.This indicates that the edge turbulence,zonal flows,andErcan be significantly enhanced by sawtooth heat pulses.

The conditional average of Hαsignals is described in figure 8(e).The Hαintensity is proportional to the plasma density in the edge region.After sawtooth crashes ∼0.8 ms,the Hαintensity rises rapidly.The observation shows that the sawteeth can also induce density pulses propagating to the edge.However,the delay time of Hαsignals with respective to sawteeth is larger than those of the LFZFs,Er,and turbulence.The possible reason is that their measurement points are not at the same radial position.

3.4.Trajectories of turbulence and flows,and model analysis

The role of turbulence in driving flows during sawtooth disruptions is another interesting problem for understanding the mechanism of sawtooth propagation in L-mode plasmas.Figures 9(a)and(b)give the trajectories of the intensity of the LFZF and turbulence,and of theErand turbulence in phase space during sawtooth cycles.Note that theEralso contains the contribution of the zonal flows or turbulence-driven flows based on the radial force balance.Significant cycles in the trajectories are shown and rotate in the clockwise direction.The rotation direction indicates that the development of the turbulence is prior to that of the LFZFs and theEr.This result suggests that the sawtooth-induced LFZFs andErmay be driven dominantly by turbulence.In addition,the LFZFs and turbulence,and theErand turbulence are all nearly out of phase,and similar results are obtained at different radial positions.

Figure 9.Trajectories of the intensities of the(a)LFZF and turbulence and of the(b)radial electric fields and turbulence in phase space in the ECRH-heated plasmas.The arrows indicate the rotation direction of the cycles.

We also observed that the intensities of both the LFZF and theErnearly linearly increase/decrease with the increase/decrease of the turbulence intensity,as shown in figure 8.This result suggests that the ratios of the LFZF power to the turbulence one and theErpower to the turbulence one nearly keep constant.

Note that the intensity of the turbulence ramps up fast,while those of the LFZF and the electric fields change a little just after sawtooth crashes.This suggests that the flows might be driven less effectively when the turbulence is below the critical value.

The sawtooth heat pulses contain not only heat pulses but also turbulence bursts.As the sawtooth heat pulse propagates to the edge,the edge pressure gradients and flows change significantly.The heat pulse and turbulence are responsible for the pressure gradient and zonal flow formations,respectively.Thus,the sawtooth effects on the flows and turbulence should link to the relative intensity of the heat pulse and turbulence burst.

To understand deeply the effects of sawtooth heat pulses on the edge flows and turbulence,a double-source predator–prey model is developed[31].Similar to the 0D model[32],four equations are utilized to describe the radial force balance and time evolutions of the ion pressure gradientP′ ,zonal flowVZF,and turbulence intensityε,respectively.

where −e,n,andBφare the electron charge,density,and toroidal magnetic field,respectively.The coefficientsai,bi,andciare the model-dependent parameters.Considering that the sawtooth heat pulse consists of heat and turbulence pulses,the heat sourceδQ(turbulence source δS)from the core enters into the equation of time evolution of the pressure gradient(turbulence intensity).These equations define a nonlinear system with two external sources.For simplicity,the mean toroidal and poloidal flows are ignored.The radial electric fields mainly come from pressure gradient and zonal flows.The flows are determined by the driving and damping effects.Turbulence is from the core and enhanced by the local gradient.The heat source mainly impacts the pressure gradient.

This model is used to analyze the interaction between flows and gradient and turbulence during sawtooth cycles through varying the ratio of theδQand δS.With lower equilibrium pressure gradienta force oscillation pattern occurs due to the sawtooth-shaped heat and turbulence sources,and this is consistent with the present measurement.The shapes of the intensities of the zonal flowδφZF,radial electric field shearand pressure gradientare all similar to those of turbulence and heat pulses.Here,a relatively strong turbulence source is selected.The turbulence and heat source are shown in figures 10(a)and(b),respectively.The turbulence source is slightly faster than the heat source.Figures 10(c)and(d)present the trajectories of the intensities of theδφZFand turbulence,and ofand turbulence in phase space,respectively.Two significant cycles appear,and all rotate in the clockwise direction.This clearly shows that the|δφZF| andfollow the turbulence.The result may qualitatively explain that the turbulence-driven flow is dominant during sawtooth cycles.Compared to the experimental observation,the nearly linear intensity dependence of the LFZF and theEron the turbulence does not appear.Also,this simulation does not show the critical value effects of the turbulence on the flows.In addition,a ‘figure-eight pattern’shown in figure 10(d)suggests that the relationship of the time sequence between the flows and turbulence changes during the sawtooth cycles.However,this is not detected in the present experiment.Note that both theand∣Er∣refer to the intensity of the shear flows.A larger intensity of theErwill cause a largerThus,the difference of the∣Er∣andshown in figures 8(b)and 9(d)can be neglected.

Figure 10.(a)Turbulence source,(b)heat source,and the trajectories of the intensities(c)of theδφZF and turbulence,and(d)of and turbulence in phase space.

Figure 11.Conditional average of the intensities of potential fluctuations in the(a)LFZF and(b)turbulence frequency bands of 0.5–3 and 20–200 kHz in various positions in L-mode plasmas with ECRH power ∼500 kW,respectively.The conditional average of the soft x-ray signals at the plasma center is given at the top of(a)and(b).

The values of various parameters used in our numerical studies are similar to those of Kimet al[32].We found that a scan of those parameters only leads to a small expansion or shrinkage of the stable regions of the fixed points of the equations,and it does not change the conclusion qualitatively.The qualitative performances of the trajectory,including the rotation direction and how many times it reverses,are dependent on the control parametersδQ,δS,and the equilibrium ion pressure gradientChanging the systematical coefficients and under the appropriate control parameters,the system can also evolve into a forced oscillation state.The detailed discussion can be found in[31].

3.5.Radial structure of the LFZF and turbulence

The radial structures and propagation of sawtooth-induced LFZFs and turbulence are investigated in the ECRH plasmas using the conditional average analysis further.Figure 11(a)shows the contour plot of the conditional average of the relative intensity of potential fluctuations in the LFZF frequency bands of 0.5–3 kHz.The relative intensity is calculated aswhereδφ f(t)is the potential fluctuation from the radial rake probe array of 12 tips,and the overline means a time averaged with the same time window for each channel.The conditional average of the soft x-ray signals at the plasma center is also shown at the top of figure 11(a).At all the positions,the LFZFs decrease(increase)before(after)sawtooth crashes.The delay time of the zonal flows with respect to sawtooth crash is ∼1 ms at the position ofr−rL=−4.8 cm,whererLis the radius of the LCFS,and the minus sign means from the LCFS inward.The delay time increases with the radial positions and reaches∼1.3 ms atr−rL=−0.4 cm.The observation suggests that the LFZF propagates outward,and its velocity is estimated as∼150 m s−1.The stronger LFZFs are observed in the interval betweenr−rL=−4.8 and −3.5 cm and betweenr−rL=−1.8 and −0.4 cm.However,in the interval betweenr−rL=−3.5 and −1.8 cm,the LFZF intensity becomes weaker.The contour of the intensity for the turbulence in the frequency bands of 20–200 kHz is shown in figure 11(b).The behavior of the delay time of the turbulence is similar to that of the LFZFs.The turbulence also propagates outward,and its velocity is the same as those of the LFZFs.In the interval betweenr−rL=−3.6 and −1.8 cm,the turbulence intensity is higher where the LFZF is weaker.The results indicate that sawteeth induce not only heat-pulse propagation but also turbulence burst and flow propagation.The edge turbulence is enhanced by turbulence pulse and leads to the increase of the LFZF intensity.

Figure 12.(a)Soft x-ray signals at plasma center,(b)Dα signals,(c)radial electric fields,(d)electron density,and(e)turbulence intensity in NBI plasmas.

3.6.Sawtooth-triggered I-phases

The characteristics of flows and turbulence in the interval between sawtooth crashes and I-phases are measured to explore the roles of turbulence and flows in sawtooth-triggered L–I transitions.The probe with two steps and 12 tips is inserted into plasmas ∼1 cm.Figures 12(a)–(e)present the soft x-ray signals,Dαsignals,Er,electron density,and turbulence intensity in the frequency bands of 20–200 kHz in NBI plasmas,respectively.The sawtooth crash occurs at 610.3 ms.Following the sawtooth crash,the L–I transition is observed at 611.2 ms.That is the delay time of the L–I transition with respect to sawtooth crash by about 0.9 ms.After the L–I transition,the Dα,Er,electron density,and turbulence intensities all become an oscillation.In the interval between 610.3 and 611.2 ms,a peaked turbulence intensity appears and corresponds to a negativeErpeak.The negative peak indicates that theEris enhanced.The phase relation between turbulence and flows is consistent with the observation earlier,where the flows and turbulence are nearly out of phase.There is no significant increase in density between sawtooth crashes and L–I transitions.Normally,the zonal flows are considered to suppress turbulence and reduce turbulent transport.Following sawtooth crashes,the turbulence reaches the edge and enhances the zonal flows.Inversely,the enhanced zonal flow suppresses turbulence,and then the plasma jumps into the I-phase.Thus,this observation suggests sawtooth heat pulses trigger L–I transition through enhancing edge turbulence and flows.

Figure 13.Probability distribution functions of the delay times for the L–I transitions,following sawtooth heat pulses in NBI plasmas.

To further explore the correlation between such L–I transitions and sawtooth crashes,the time delay of the L–I transitions with respect to sawtooth crashes is analyzed statistically.The probability density function(PDF)of the delay time for the L–I transitions following the sawtooth crashes is given in figure 13.Over 100 of such L–I transitions are included for this analysis.The higher value of the PDF is shown in the interval of ∼0.3–1.2 ms,and a significant peak in the PDF appears at ∼0.6 ms.The analysis indicates that the L–I transitions are most likely to happen at ∼0.3–1.2 ms after sawtooth crashes,especially at ∼0.6 ms.However,if the delay time is less than 0.2 ms or more than 1.5 ms,the L–I transition might not be caused by sawtooth crashes because of the small values of the PDF.The observation indicates that the delay time of L–I transitions with respect to sawtooth crashes is comparable to that of flows and turbulence in the ECRH plasmas ∼1 ms as mentioned earlier.The result also suggests that the L–I transitions can be caused by increasing flows due to sawtooth crashes.

4.Conclusion and discussion

Sawtooth heat-pulse propagation is an important issue in the fusion field.However,the flow formation mechanisms during sawtooth cycles have not attracted much attention.Previous studies mainly focused on sawtooth-induced density and heatpulse propagations.The heat flows and density-pulse propagation can induce temperature,density,and pressure gradient propagations.In fact,not only the density and heat-pulse propagations but also turbulence clump propagation can be induced by sawteeth.Generally speaking,both gradients and turbulence contribute to flow formations.Here,the edge flows and turbulence are detected during sawtooth cycles,and a double-source predator–prey model analysis is carried out.The radial electric fields,zonal flows,and turbulence are significantly enhanced due to sawteeth.The development of the turbulence is prior to the radial electric fields and zonal flows.The intensities of both the zonal flows and electric fields nearly linearly increase/decrease with the increase/decrease of the turbulence intensity.The flows might be driven less effectively when the turbulence is below the critical value.The model analysis can only be a part of an experimental observation,just the rotation direction of hysteresis,not the other characteristics of the observation.The same rotation direction of the hystereses for the experimental observation and model calculation suggests that a relatively strong turbulence pulse is a benefit for the dominant zonal flow formation and thus L–I transitions.

The delay time of the edge electric fields,zonal flows,and turbulence with respect to the sawtooth crash was first evaluated as ∼1 ms.Note that the importance of the delay time is embodied by the study of not only the sawtooth propagation but also the sawtooth-triggered transitions.Generally speaking,the flows are favorable for confinement regime transitions.Thus,the delay time is a key parameter to understand the underlying physics of sawtooth-induced confinement regime transitions.The fact that the estimated delay time ∼1 ms in L-mode plasmas is comparable to that of the sawtooth-triggered L–I transitions suggests that the sawtooth heat pulses trigger L–I transitions through increasing turbulence-driven flows.Furthermore,the enhancements of the radial electric fields and turbulence are observed proceeding the L–I transitions and following the sawtooth crashes.

Acknowledgments

This work was supported by National Natural Science Foundation of China(Nos.12075057,11775069,11320101005,and 11875020);the National Magnetic Confinement Fusion Science Program of China(No.2017YFE0301201);East China University of Technology,Doctoral Foundation(Nos.DHBK 2017134 and DHBK 2018059);Grant-in-Aid for Scientific Research of the Japan Society for the Promotion of Science(Nos.15H02155,15H02335,21K03513);Landmark Achievements in Nuclear Science and Technology(No.xxkjs2018011);and Natural Science Foundation of Jiangxi Province(Nos.20202ACBL201002 and 0192ACB80006).

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