Electron pressure anisotropy drives the growth rate of the tearing instability and sustains plasmoid-mediated magnetic reconnection in laboratory high-energy-density plasmas without classical resistivity.
Small-scale perturbations emerge within the widened region, signaling the initial stages of cur- rent sheet destabilization and the onset of plasmoid formation
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Laboratory evidence of electron pressure anisotropy driving plasmoid mediated magnetic reconnection
Electron pressure anisotropy drives the growth rate of the tearing instability and sustains plasmoid-mediated magnetic reconnection in laboratory high-energy-density plasmas without classical resistivity.