Helioseismological determination of the subsurface spatial spectrum of solar convection: Demonstration using numerical simulations

Abstract: Context. Understanding convection is important in stellar physics, for example, when it is an input in stellar evolution models. Helioseismic estimates of convective flow amplitudes in deeper regions of the solar interior disagree by orders of magnitude among themselves and with simulations. Aims. We aim to assess the validity of an existing upper limit of solar convective flow amplitudes at a depth of 0.96 solar radii obtained using time-distance helioseismology and several simplifying assumptions. Methods. W… Show more

“…The native asymmetries, the roles of rotation and differential rotation are all essential components that are reasonably well understood. However helioseismology, while resolving the solar interior, has also shown more recently that subsurface convective motions u rms are at least an order of magnitude weaker (at r ≈ 0.96R ) than theory suggests [37,38], which if confirmed begs the worrying question of what transports the solar luminosity there. Nevertheless it must generate some α-effect and link large-and small-scales through non-linear terms that may be deterministic only in a global (i.e.…”

The mercurial Sun at the heart of our solar system

“…The native asymmetries, the roles of rotation and differential rotation are all essential components that are reasonably well understood. However helioseismology, while resolving the solar interior, has also shown more recently that subsurface convective motions u rms are at least an order of magnitude weaker (at r ≈ 0.96R ) than theory suggests [37,38], which if confirmed begs the worrying question of what transports the solar luminosity there. Nevertheless it must generate some α-effect and link large-and small-scales through non-linear terms that may be deterministic only in a global (i.e.…”

The mercurial Sun at the heart of our solar system