SUMMARY Tidal loading causes fluid flow through permeable seafloor and between regions of contrasting elastic properties or porosity within subsea formations. We examine theoretically the dissipation of energy by these flows and its global significance as a mechanism for tidal energy dissipation. Expressions are given for energy dissipation rates in layered formations due to vertical flow caused by tidal loading, but the results can be used to constrain dissipation by other flow patterns. We consider flow near the seafloor, in gas-bearing sediments, and in highly fractured permeable igneous crust. Energy dissipation by the first two mechanisms is negligibly small globally, although it may be locally significant under extreme conditions. Under favourable conditions, flow in fractured crust may have greater energy dissipation, but the total amount is limited by the thickness of the permeable layer. Based on our current understanding of subsea hydrogeology, tidally induced flow in subsea formations appears to make little contribution to the observed global tidal energy dissipation.
[1]
J. Gale,et al.
Theory of earth tide and barometric effects in porous formations with compressible grains
,
1983
.
[2]
G. Platzman.
Planetary energy balance for tidal dissipation
,
1984
.
[3]
Kelin Wang,et al.
An unequivocal case for high Nusselt number hydrothermal convection in sediment-buried igneous oceanic crust
,
1997
.
[4]
C. E. Jacob.
On the flow of water in an elastic artesian aquifer
,
1940
.
[5]
Ernst J. O. Schrama,et al.
A preliminary tidal analysis of TOPEX/POSEIDON altimetry
,
1994
.
[6]
R. D. Ray,et al.
Detection of tidal dissipation in the solid Earth by satellite tracking and altimetry
,
1996,
Nature.
[7]
Earl E. Davis,et al.
Theory for the propagation of tidally induced pore pressure variations in layered subseafloor formations
,
1996
.
[8]
A. Fisher.
Permeability within basaltic oceanic crust
,
1998
.