3.2.1. Blob stretched by the strong sheared E × B flow

The cross-correlation function (CCF) was utilized to reconstruct a two-dimensional (2-D) coherent structure depending on the significant long-range correlation along the same magnetic field line (Grulke et al. Reference Grulke, Klinger, Endler and Piel2001; Cheng et al. Reference Cheng, Dong, Yan, Itoh, Zhao, Hong, Huang, Nie, Lan and Liu2013). A region with poloidal–radial dimensions of $36 \times 36\;\textrm{m}{\textrm{m}^2}$ was established with the combined poloidal (array A) and radial (array B) probe arrays that were toroidally separated by ${L_\varphi } = 2100\;\textrm{mm}$. The CCF was computed from two types of ion saturation signals: the reference signal ${S_x}(i)$ was obtained from the poloidal array A $(1 \le i \le 10)$ and ${S_y}(i)$ was obtained from the radial array B $(11 \le j \le 20)$, where i and j denote the probe positions in the poloidal and radial probe arrays, respectively, as sketched in figure 1. The correlation coefficient of the CCF was estimated at zero time lag and placed at the point in the matrix, i.e. ${\gamma _{\textrm{max}}}(i,j)$. Following this method, the contour of the correlations was obtained. The calculated matrix displays a contour for the 2-D image of the coherent structure. Figures 5(a)–5(c) display the 2-D images of the coherent structure with different sheared E × B flows. The blob poloidal correlation length for the three different E × B shearing rates was roughly estimated as 0.5 cm, 1.1 cm and 1.5 cm by the e-folding decay spatial scale of the CCF, which is qualitatively consistent with the results estimated by two-point correlation method (Beall, Kim & Powers Reference Beall, Kim and Powers1982) ${L_c} = 1/\langle {\sigma _k}\rangle$, where $\langle \sigma _k^2\rangle = \sum\nolimits_f {[\sum\nolimits_k {{{[k - \bar{k}(f)]}^2}} \cdot s(k|f)]}$, $s(f)$ denotes the spectral density, f and k denote the frequency and wavenumber, respectively. It was found that the blob poloidal correlation length was increased by approximately three times whereas the radial correlation length has less pronounced change as the E × B sheared flow rises from ${\omega _{E \times B}} = 0.12 \times {10^5}$ to $1.08 \times {10^5}\;{\textrm{s}^{ - 1}}$, implying that strong E × B shear flow has an ability to stretch coherent structures. A similar experimental result has been reported in other devices (Carter & Maggs Reference Carter and Maggs2009). Here, we compare theoretical predictions of critical velocity shear with experimental observations reported in this work. According to the theoretical prediction (Yu & Krasheninnikov Reference Yu and Krasheninnikov2003), the magnitude $({\varPhi ^{\textrm{crit}}})$ of critical potential was calculated as ${\varPhi ^{\textrm{crit}}} = {T_e} \cdot \varPhi _{\textrm{nor}}^{\textrm{crit}}/e$, where T_e represents electronic tempreture, e is elementary charge and $\varPhi _{\textrm{nor}}^{\textrm{crit}}$ means the normalized magnetite of potential related to the critical velocity shear, which could be addressed as $\varPhi _{\textrm{nor}}^{\textrm{crit}} = {({\delta _s}/2{\rho _s})^3}({\delta _b}/L)$, where ${\rho _s} \approx 0.046\;\textrm{cm}$, connection length $L \approx 2.1 \times {10^3}\;\textrm{cm}$, blob size ${\delta _b} \approx 1.6\;\textrm{cm}$ and width of E × B shear layer ${\delta _s} \approx 1.0\;\textrm{cm}$, where ρ_s is Larmer radius. Using the plasma parameters ${T_e} \approx \; 18\;\textrm{eV}$ $\varPhi _{\textrm{nor}}^{\textrm{crit}} \approx 0.98$, the estimated magnitude ${\varPhi ^{\textrm{crit}}}$ was about 17.6 V, which is very close to the experimental observation ≈15 V.

Figure 5. Contour plot of the coherence between array A and array B toroidally separated by 2100 mm for different E × B shearing rates ${\omega _{E \times B}} = 0.12 \times {10^5}\;{\textrm{s}^{ - 1}}$ (a), $\; {\omega _{E \times B}} = 0.48 \times {10^5}\;{\textrm{s}^{ - 1}}$ (b) and ${\omega _{E \times B}} = 1.08 \times {10^5}\;{\textrm{s}^{ - 1}}$ (c).

The statistical distribution of the blob poloidal correlation lengths against the blob amplitudes with different E × B shearing rates was analysed and presented in figure 6. It was clearly seen that the blob poloidal correlation length monotonically rises with increasing E × B shearing rate for different blob amplitudes. An interesting observation here is that the maximum variation of the poloidal correlation length for large blobs $(3.5\sigma )$ occurred in the strong E × B sheared flow case $({\omega _{E \times B}} = 1.05 \times {10^5}\;{\textrm{s}^{ - 1}})$. Here, it should be pointed out that the estimated E × B shearing rate is slightly lower than the blob decorrelation rate $1/{\tau _c} \approx 1.1 \times {10^5}\;{\textrm{s}^{ - 1}}$ (where ${\tau _c}$ represents the blob lifetime inferred from the full width at half-maximum magnitude), concluding that blobs were not torn up by the E × B flow (only stretching blobs). A similar experimental result on the blob stretched by the radio-frequency induced sheared flow in far SOL has been reported by (Zhang et al. Reference Zhang, Cziegier, Bobkov, Conway, Fuchert, Griener, Kardaun, Manz, Noterdaeme and Seliunin2019). In fact, a strong enough sheared E × B flow via biasing can directly split the edge turbulent eddy structure and consequently cause the confinement improvement evidenced in TEXTOR (Shesterikov et al. Reference Shesterikov, Xu, Hidalgo, Berte, Dumortier, Schoor, Vergote and Van Oost2012).

Figure 6. Statistical analysis of blob poloidal correlation length as a function of blob amplitude for the different E × B shearing rates ${\omega _{E \times B}}$. The probe measurement is localized at Δr = +10 mm.

3.2.2. Blobs deceleration due to the poloidal elongation

Conditional average was widely used to extract coherent structure from a turbulent signal in fusion plasmas and is generally defined as

(3.4)\begin{equation}{y_{\textrm{cond}}}(\tau ) = \frac{1}{N}\sum\limits_{i = 1}^N {[y({t_i} + \tau )|x({t_i}) = {\phi _c}]} ,\end{equation}

where $x(t)$ is the reference signal and $y(t)$ is the analysed signal. When the pre-set condition is met, the time t, becomes the reference time $\tau = 0$, and a subset from the analysed signal is taken around $\tau = 0$, from $- {\tau _{\textrm{max}}}$ to ${\tau _{\textrm{max}}}$. After searching the full reference signal for N occurrences of the condition, ${\phi _c}$, a set of N waveforms from the analysed signal are assembled. This set is then ensemble averaged to give the conditional average for the condition ${\phi _c}$ (Filippas et al. Reference Filippas, Bengston, Li, Meier, Ritz and Powers1995). In our analysis, the threshold $+ 2.5\sigma$ is used to detect the blobs. In cross-conditional average (CCA) analysis, the ion saturation current (as a proxy of plasma density) was routinely chosen as the reference signal. The conditional average was obtained by recording 120 data points (window length) around the maximum of each burst event, i.e. [−60 μs, +60 μs], and then accumulating and averaging the selected events.

Blob radial motion is widely accepted to be driven by the E × B formed within blobs (Krasheninnikov Reference Krasheninnikov2001), which is expressed as

(3.5)\begin{equation}\tilde{V}_r^{\textrm{blob}} = {\tilde{E}_{\theta ,\textrm{blob}}}/{B_t} = ({\tilde{V}_{f,\textrm{blob}}}/L{c_{\theta ,\textrm{blob}}})B_t^{ - 1},\end{equation}

where ${\tilde{V}_{f,\textrm{blob}}}$ represents the interior potential difference within the correlation length $L{c_{\theta ,\textrm{blob}}}$. The blob radial velocity $(\tilde{V}_r^{\textrm{blob}})$ was estimated with the reference signal $({I_s})$ based on the CCA with $> 2.5\sigma$ thresholds. Furthermore, it is generally observed that the floating potential in the blob has a dipole structure. Here, $\Delta {V_{f,\textrm{blob}}}$ and $L{c_{\theta ,\textrm{blob}}}$ are both key parameters for determining blob radial motion, and they are affected by numerous factors (Labombard et al. Reference Labombard, Boivin, Greenwald, Hughes and Group2001) such as collisionality, spin and the sheared E × B flow. To clarify the inherent physics governing the blob dynamics, we computed the radial velocity and floating potentials of blobs (>2.5σ) measured at Δr = +10 mm, where the E × B shearing rate ${\omega _{E \times B}}$ changes from $0.15 \times {10^5}$ to $1.0 \times {10^5}\;{\textrm{s}^{ - 1}}$ and internal potential compared has less change in figure 7. It was found that the blob radial velocity gradually decreased from 1.63 km s⁻¹ to 0.82 km s⁻¹, whereas the potential difference inside blobs stayed almost unchanged when the local E × B shearing rate was increased, as sketched in figure 7(b). Here, the plasma collisionality was estimated to be $v_{\textrm{ei}}^\ast \; \approx 20\unicode{x2013} 23$ ($v_{\textrm{ei}}^\ast{=} {L_\parallel }/{\lambda _{\textrm{ei}}} \approx {10^{ - 16}}{L_\parallel }{n_e}T_e^{ - 2}$, where ${L_\parallel }$ denotes magnetic correlation length) during the plasma current ramp-up from 155 to 175 kA, the less prominent variation of $v_{\textrm{ei}}^\ast$ reflects that the effect of plasma collisionality on the potential could be negligible. These observed results indicate that the reduction of the blob radial velocity is mainly due to its poloidal elongation $(L{c_{\theta ,\textrm{blob}}})$. This is direct experimental evidence of the significant role played by the sheared E × B flow in blob radial motion via the poloidal elongation.

Figure 7. Comparison of blob radial velocity (a) and its internal potential (b) with amplitude >2.5σ estimated by CCA in the scenarios with different E × B flow shearing rates ${\omega _{E \times B}}$. The measured radial position is at Δr = +10 mm.

3.3. Localized density gradient possibly effected by blob radial motion

To study the potential effect of blob radial motion on the localized density gradient, we present the time trace of the E × B shearing rate together with the normalized density fluctuation, the blob radial velocity as well as the density gradient in figure 8. The four-tip probe localized at the outer-mid plane (Δr ≈ +10 mm) was used to measure the normalized density fluctuation and blob radial velocity. Each point was estimated with approximately 20 ms data, and the red shaded area denotes the error bar calculated with the standard deviation as $(i) = \sqrt {(1/(N - 1))\sum\nolimits_{i = 1}^N {{{({x_i} - \bar{x})}^2}} }$, were ${x_i}$ denotes the time series of the signal. It was found that the significant change of the E × B sheared rate occurs at about t = 850 ms, however, the normalized density fluctuation has a less pronounced variation as compared in figure 9(a), suggesting that the increased E × B sheared flow has no significant effect on the ambient turbulence in this region. On the other hand, the localized density gradient actually starts to dramatically rise from t = 850 ms, while the blob radial velocity accordingly reduces. These observed results reveal the crucial role played by the blob radial motion in the localized density gradient.

Figure 8. The time traces of the E × B flow shearing rate together with normalized density fluctuation (a), the blob radial velocity $( > 2.5\sigma )$ (b) and the inverse scale length of density gradient (c), The probe measurement position is approximately localized at Δr = +10 mm.

Figure 9. Blob radial velocity and density gradient against the E × B shearing rate. The measure radial position is at the normalized radial position at Δr = +10 mm.

To obtain the statistical relation between localized density gradient and blob radial velocity, we have chosen a series of discharges with different SOL E × B shearing rates. All the discharges were ohmically heated plasmas with similar parameters including ${B_t}$ and the line-averaged density $({n_{\textrm{el}}})$. The probe measure position is localized at the near SOL, Δr = +10 mm. Figure 9 plots the blob radial velocity $(\tilde{V}_r^{\textrm{blob}})$ and the inverse scale of density gradient $(L_{{n_e}}^{ - 1})$ against the E × B shearing rate $\textrm{(}{\omega _{E \times B}})$. It is seen that the $\tilde{V}_r^{\textrm{blob}}$ monotonically decreases, whereas the density gradient increases as the SOL localized E × B shearing rate gradually rises from 0.6 × 10⁵ to 1.1 × 10⁵ s^-1. These observations suggest that a strong E × B sheared flow has a pronounced impact on slowing the blob radial motion, which was suggested to be related to the increased density observed in this experiment.