Smoldering is a slow combustion process in a porous medium in which he
at is released by oxidation of the solid. If the material is sufficien
tly porous to allow the oxidizer to easily filter through the pores, a
smolder wave can propagate through the interior of the solid. We cons
ider samples closed to the surrounding environment except at the ends,
with gas forced into the sample through one of the ends. A smolder wa
ve is initiated at the Ether end and propagates in a direction opposit
e to the flow of the oxidizer. previous experimental results show that
for opposed flow smolder, decomposition of the solid fuel into char i
s the chemical process which drives the smolder process. We model this
decomposition as a one step reaction. The model suggests that extinct
ion occurs when decomposition is complete. We employ large activation
energy asymptotic methods to find uniformly propagating, planar smolde
r wave solutions. We determine their propagation velocity, burning tem
perature, final degree of fuel decomposition, and extinction limits. W
e also determine spatial profiles of gas flux, oxidizer concentration,
temperature, and degree of decomposition of the solid. Comparison is
made with previous experimental results.