Laboratory study of low-b forces in arched, line-tied magnetic
flux ropes
Authors: C. E. Myers, M. Yamada, H. Ji, J.
Yoo, J. Jara-Almonte, and W. Fox
Abstract: The loss-of-equilibrium is a solar eruption
mechanism whereby a sudden breakdown of the magnetohydrodynamic
force balance in the Sun's corona ejects a massive burst of
particles and energy into the heliosphere. Predicting a
loss-of-equilibrium, which has more recently been formulated as
the torus instability, relies on a detailed understanding of the
various forces that hold the pre-eruption magnetic flux rope in
equilibrium. Traditionally, idealized analytical force expressions
are used to derive simpli ed eruption criteria that can be
compared to solar observations and modeling. What is missing,
however, is a validation that these idealized analytical force
expressions can be applied to the line-tied, low-aspect-ratio
conditions of the corona. In this paper, we address this
shortcoming by using a laboratory experiment to study the forces
that act on long-lived, arched, line-tied magnetic flux ropes.
Three key force terms are evaluated over a wide range of
experimental conditions: (1) the upward hoop force; (2) the
downward strapping force; and (3) the down-ward toroidal field
tension force. First, the laboratory force measurements show that,
on average, the three aforementioned force terms cancel to produce
a balanced line-tied equilibrium. This finding validates the
laboratory force measurement techniques developed here, which were
recently used to identify a dynamic toroidal fi eld tension force
that can prevent flux rope eruptions [Myers et al., Nature 528,
526 (2015)]. The verification of magnetic force balance also
con firms the low- assumption that the plasma thermal pressure is
negligible in these experiments. Next, the measured force terms
are directly compared to their corresponding analytical
expressions. While the measured and analytical forces are found to
be well correlated, the low- aspect-ratio, line-tied conditions in
the experiment are found to both reduce the measured hoop force
and increase the measured tension force with respect to analytical
expectations. These two co-directed effects combine to generate
laboratory flux rope equilibria at lower altitudes than are
predicted analytically. Such considerations are expected to modify
the loss-of-equilibrium eruption criteria for analogous flux ropes
in the solar corona.
Submitted to: Physical Review Letters
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