Nengchao Wang scite author profile

Toroidal computations are performed using the MARS-F code [Liu Y Q et al 2000 Phys.Plasmas 7 3681], in order to understand correlations between the plasma response and the observed mitigation of the edge localized modes (ELM) using resonant magnetic perturbation fields in ASDEX Upgrade. In particular, systematic numerical scans of the edge safety factor reveal that the amplitude of the resonant poloidal harmonic of the response radial magnetic field near the plasma edge, as well as the plasma radial displacement near the X-point, can serve as good indicators for predicting the optimal toroidal phasing between the upper and lower rows of coils in ASDEX Upgrade. The optimal coil phasing scales roughly linearly with the edge safety factor 95 q , for various choices of the toroidal mode number n=1-4 of the coil configuration. The optimal coil phasing is also predicted to vary with the upper triangularity of the plasma shape in ASDEX Upgrade. Furthermore, multiple resonance effects of the plasma response, with continuously varying 95 q , are computationally observed and investigated.

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Study of the penetration of resonant magnetic perturbations in J-TEXT

Wang

Ren

et al. 2014

Nucl. Fusion

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In the J-TEXT tokamak, the penetration of resonant magnetic perturbations (RMPs) has been studied by using a set of in-vessel RMP coils. It is found that, once the RMP amplitude exceeds a critical value, the applied RMP can lead to field penetration and excitation of a large locked mode in the tearing-stable plasma. The sawtooth oscillations disappear and the confinement deteriorates significantly accompanied by tearing mode excitation. For the plasma with an initial high frequency tearing mode, the RMP can suppress the tearing mode, and field penetration followed with a further increased RMP. The relationship between the RMP penetration threshold and the electron density has been investigated for tearing-stable plasmas. It is found that the penetration threshold increases with the density and scales proportionally to in the ranges of (0.7–2.7) × 1019 m−3. Using the experimental parameters as input, the numerical modelling based on two-fluid equations gives the scaling of , which approximately agrees with the experimental density scaling.

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Wearable Electronics Based on the Gel Thermogalvanic Electrolyte for Self-Powered Human Health Monitoring

Bai

Wang

Yang

et al. 2021

ACS Appl. Mater. Interfaces

101

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There is always a temperature difference of more than 10 degrees between the human body, as a sustainable heat source, and the ambient temperature. Converting body heat into electricity that in turn is used to drive personal medical electronics is of significance in smart wearable medicine. To avoid the frangibility and complex preparation of traditional thermoelectric materials, we fabricated a gel electrolyte-based thermogalvanic generator with Fe 3+ /Fe 2+ as a redox pair, which presents not only moderate thermoelectric performance but also excellent flexibility. With a micropore-widespread polyvinylidene fluoride diaphragm implanted in the gel, a thermal barrier was created between the two halves, effectively improving the Seebeck coefficient by reducing its thermal conductivity. Considering the superior temperature response of the gel, a self-powered body temperature monitoring system was established by conformally affixing it to the forehead. Meanwhile, the gel patch with a high specific heat capacity can effectively cool down fever patients. This work may offer a new train of thought for exploiting self-powered wearable medical electronics by scavenging low-grade body heat.

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Nengchao Wang

Lattice BGK Model for Incompressible Navier–Stokes Equation

Modelling plasma response to RMP fields in ASDEX Upgrade with varying edge safety factor and triangularity

Study of the penetration of resonant magnetic perturbations in J-TEXT

Wearable Electronics Based on the Gel Thermogalvanic Electrolyte for Self-Powered Human Health Monitoring

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