On the Propagation and Damping of Alfvenic Fluctuations in the Outer Solar Corona and Solar Wind
Abstract
We analyze Parker Solar Probe and Solar Orbiter observations to investigate the propagation and dissipation of Alfv\'enic fluctuations from the outer corona to 1~AU. Conservation of wave-action flux provides the theoretical baseline for how fluctuation amplitudes scale with the Alfv\'en Mach number Ma, once solar-wind acceleration is accounted for. Departures from this scaling quantify the net balance between energy injection and dissipation. Fluctuation amplitudes follow wave-action conservation for Ma < Mab but steepen beyond this break point, which typically lies near the Alfv\'en surface (Ma ≈ 1) yet varies systematically with normalized cross helicity σc and fluctuation scale. In slow, quasi-balanced streams, the transition occurs at Ma 1; in fast, imbalanced wind, WKB-like scaling persists to Ma 1. Outer-scale fluctuations maintain wave-action conservation to larger Ma than inertial-range modes. The turbulent heating rate Q is largest below Mab, indicating a preferential heating zone shaped by the degree of imbalance. Despite this, the Alfv\'enic energy flux Fa remains elevated, and the corresponding damping length d = Fa/Q remains sufficiently large to permit long-range propagation before appreciable damping occurs. Normalized damping lengths d/HA, where HA is the inverse Alfv\'en-speed scale height, are near unity for Ma Mab but decline with increasing Ma and decreasing U, implying that incompressible reflection-driven turbulence alone cannot account for the observed dissipation. Additional damping mechanisms -- such as compressible effects -- are likely required to account for the observed heating rates across much of the parameter space.
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