A three-dimensional mathematical model simulates virgin groundwater fl
ow in the Big Horn basin, Wyoming. The computed results are compared t
o two published interpretations of the Tensleep Sandstone virgin poten
tiometric surface; both of these interpretations, Bredehoeft and Benne
tt, and Haun, were made from the same data set. The published maps are
quite different. Bredehoeft and Bennett ignored the faults; Haun trea
ted the faults as horizontal barriers to flow. The hydraulic head at d
epth over much of the Big Horn basin is near the land surface elevatio
n, a condition usually defined as hydrostatic. This condition indicate
s a high, regional-scale, vertical conductivity for the sediments in t
he basin. Our hypothesis to explain the high conductivity is that the
faults act as vertical conduits for fluid flow. These same faults can
act as either horizontal barriers to flow or nonbarriers, depending up
on whether the fault zones are more permeable or less permeable than t
he adjoining aquifers. A three-dimensional simulation of fluid flow in
the basin indicates that either of the potentiometric interpretations
, that of Bredehoeft and Bennett or that of Haun, can be reproduced. T
he results depend upon whether the fault zones are lateral barriers to
flow. In the case where the faults are lateral barriers, the basin is
broken into compartments with much of the areal head loss occurring a
cross the fault zones.