Laboratory experiments demonstrate that stellar-strength magnetic fields fully suppress coronal mass ejection propagation through kink instability.
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3 Pith papers cite this work. Polarity classification is still indexing.
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Confined flares exhibit total Lorentz force change below 1.8 × 10^22 dyne along the PIL, separating them from eruptive flares in a sample of 37 major events observed 2011-2017.
3D MHD simulation of successive flux-rope eruptions shows reconnection flux accumulating linearly with CME velocity, consistent with HMI/AIA observations of one event.
citing papers explorer
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Experimental evidence for coronal mass ejection suppression in strong stellar magnetic fields
Laboratory experiments demonstrate that stellar-strength magnetic fields fully suppress coronal mass ejection propagation through kink instability.
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Photospheric Lorentz force changes in eruptive and confined solar flares
Confined flares exhibit total Lorentz force change below 1.8 × 10^22 dyne along the PIL, separating them from eruptive flares in a sample of 37 major events observed 2011-2017.
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Evolution of reconnection flux during eruption of magnetic flux ropes
3D MHD simulation of successive flux-rope eruptions shows reconnection flux accumulating linearly with CME velocity, consistent with HMI/AIA observations of one event.