Bounds on convective heat transport in a porous layer heated from below are
derived using the background field variational method (Constantin & Doerin
g 1995a, b, 1996; Doering & Constantin 1992, 1994, 1996; Nicodemus, Holthau
s & Grossmann 1997a) based on the technique introduced by Hopf (1941). We c
onsider the infinite Prandtl-Darcy number model in three spatial dimensions
, and additionally the finite Prandtl-Darcy number equations in two spatial
dimensions, relevant for the related Hele-Shaw problem. The background fie
ld method is interpreted as a rigorous implementation of heuristic marginal
stability concepts producing rigorous limits on the time-averaged convecti
ve heat transport, i.e. the Nusselt number Nu, as a function of the Rayleig
h number Ra. The best upper bound derived here, although not uniformly opti
mal, matches the exact Value of Nu up to and immediately above the onset of
convection with asymptotic behaviour, Nu less than or equal to 9/256 Ra as
Ra --> infinity, exhibiting the Howard-Malkus-Kolmogorov-Spiegel scaling a
nticipated by classical scaling and marginally stable boundary layer argume
nts. The relationship between these results and previous works of the same
title (Busse & Joseph 1972; Gupta & Joseph 1973) is discussed.