The nonlinear propagation of Alfv6n waves on open solar magnetic flux tubes is considered.The flux tubes are taken to be vertical and axisymmetric, and they are initially untwisted. The Alfv6n waves are time-dependent axisymmetric twists. Their propagation into the chromosphere and corona is investigated by solving numerically a set of nonlinear time-dependent equations, which couple the Alfv6n waves into motions parallel to the initial magnetic field (motion in the third coordinate direction is artificially suppressed). The principal conclusions are: (1) Alfv6n waves can steepen into fast shocks in the chromosphere. These shocks can pass through the transition region into the corona, and heat the corona.(2) As the fast shocks pass through the transition region, they produce large-velocity pulses in the direction transverse to Bo. The pulses typically have amplitudes of 60 km s -1 or so and durations of a few tens of seconds. Such features may have been observed, suggesting that the corona is in fact heated by fast shocks.(3) Alfv6n waves exhibit a strong tendency to drive upward flows, with many of the properties of spicules. Spicules, and the observed corrugated nature of the transition region, may therefore be by-products of magnetic heating of the corona. (4) It is qualitatively suggested that Alfv6n waves may heat the upper chromosphere indirectly by exerting time-dependent forces on the plasma, rather than by directly depositing heat into the plasma.
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