Abstract
Between the base of the solar corona at $r=r_\textrm {b}$ and the Alfvén critical point at $r=r_\textrm {A}$ , where $r$ is heliocentric distance, the solar-wind density decreases by a factor $ \mathop > \limits_\sim 10^5$ , but the plasma temperature varies by a factor of only a few. In this paper, I show that such quasi-isothermal evolution out to $r=r_\textrm {A}$ is a generic property of outflows powered by reflection-driven Alfvén-wave (AW) turbulence, in which outward-propagating AWs partially reflect, and counter-propagating AWs interact to produce a cascade of fluctuation energy to small scales, which leads to turbulent heating. Approximating the sub-Alfvénic region as isothermal, I first present a brief, simplified calculation showing that in a solar or stellar wind powered by AW turbulence with minimal conductive losses, $\dot {M} \simeq P_\textrm {AW}(r_\textrm {b})/v_\textrm {esc}^2$ , $U_{\infty } \simeq v_\textrm {esc}$ , and $T\simeq m_\textrm {p} v_\textrm {esc}^2/[8 k_\textrm {B} \ln (v_\textrm {esc}/\delta v_\textrm {b})]$ , where $\dot {M}$ is the mass outflow rate, $U_{\infty }$ is the asymptotic wind speed, $T$ is the coronal temperature, $v_\textrm {esc}$ is the escape velocity of the Sun, $\delta v_\textrm {b}$ is the fluctuating velocity at $r_\textrm {b}$ , $P_\textrm {AW}$ is the power carried by outward-propagating AWs, $k_\textrm {B}$ is the Boltzmann constant, and $m_\textrm {p}$ is the proton mass. I then develop a more detailed model of the transition region, corona, and solar wind that accounts for the heat flux $q_\textrm {b}$ from the coronal base into the transition region and momentum deposition by AWs. I solve analytically for $q_\textrm {b}$ by balancing conductive heating against internal-energy losses from radiation, $p\,\textrm {d} V$ work, and advection within the transition region. The density at $r_\textrm {b}$ is determined by balancing turbulent heating and radiative cooling at $r_\textrm {b}$ . I solve the equations of the model analytically in two different parameter regimes. In one of these regimes, the leading-order analytic solution reproduces the results of the aforementioned simplified calculation of $\dot {M}$ , $U_\infty$ , and $T$ . Analytic and numerical solutions to the model equations match a number of observations.
Highlights
Pioneering works by Parker (1958, 1965), Hartle & Sturrock (1968), and Durney (1972)modelled the solar wind as a steady-state, spherical outflow powered by the outward conduction of heat from the base of the corona
It is worth noting that in contrast to δv, fchr, and δv eff, which are plausibly independent of the properties of the coronal plasma and coronal magnetic field, δvb depends upon ρb, which varies between different flux tubes with different super-radial expansion factors ηb, as shown later in (3.55)
The various quantities appearing in the model equations can be divided into five groups: (1) quantities that are determined observationally (R, M, vesc, ρ, ρ, ψ, δv eff, B ); (2) free parameters (σ, lb); (3) the super-radial expansion factor η(r), which takes on different values in different magnetic flux tubes and in different models for the solar magnetic field; (4) the three principal unknowns, yb, yc, and x; and (5) additional unknowns that can be determined once yb, yc, and x are found (M, χH, U(r), ρb, qb, vAb, rc, rA)
Summary
Pioneering works by Parker (1958, 1965), Hartle & Sturrock (1968), and Durney (1972). Approximate expressions for M , U∞, and the coronal temperature can be quickly obtained by modelling the solar wind as a spherically symmetric, steady-state outflow and assuming that: (1) AW turbulence is the dominant heating mechanism; (2) solar rotation can be neglected, so that the magnetic field B and flow velocity are aligned; (3) B ∝ r−2r, where ris the radial unit vector (i.e. a split monopole, with Br > 0 in one hemisphere and Br < 0 in the other); (4) momentum deposition by AWs can be neglected between the coronal base and sonic critical point; and (5) p dV work is the dominant sink of internal energy in the sub-Alfvénic region of the solar wind, in which the solar-wind outflow velocity U is smaller than the Alfvén speed vA.
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