examples which illustrate this geometrical rela- tionship. Beneath a convex glacier surface the top of a water reservoir would be in concave shape. For such a configuration a depression would have to be present in the glacier bed. Beneath a concave glacier surface a reservoir has a convex shape, rising above the bed. The bed-rock itself may even be convex. Given maps of a glacier surface and the glacier bed-rock one can determine whether a reservoir is to be expected at the glacier bed. Temperate glaciers are considered to be per- meable to water (Nye ancL Frank 1973, Nye in press). The flow of water in a cross-section can be described by the potential distribution (7) (p (x, z, t) = pw g (z - z0) + p in which p is the water pressure in the water passages, x and z are the horizontal and the vertical coordinates, respectively, z0 is an arbitr- ary datum level and t is the time. The water pressure inside the ice may be estimated equal to the ice overburden pressure pf = p{ g (zs — z), in which zs is the elevation of the glacier sur- face. The family of equipotential curves Cp (x, z, t) = C = constant illustrates the flow of water in the cross-section. These curves are given by In an isotropic permeable medium the stream- lines would be perpendicular to the equipo- tential lines. Figs. 3 a and b show the potential distribu- tion in a cross-section. The location of the datum level needs some explanation. The re- servoir has a shape which gives an equilibrium of vertical forces such that the overlying glacier floats in an isostatic equilibrium (one consequ- ence of Equation (2)). A horizontal datum line z0 can be placed above the reservoir. The height of the datum line may be chosen such that the equipotential line (surface in three dimensions) cp = 0; (C = 0) marks the roof of the water reservoir. This elevation is found by adding the height (pi/pw) Hj (that is °/io of the ice thick- ness) to the top of the water reservoir. This datum level is a convenient reference level for the overburden pressure at the glacier bed. — According to Equation (8), the surface of the water reservoir is the mirror image, magnified vertically by the factor pi/(pw —Pi); of the glacier surface about the datum level. The same result is given in Equation (6). The other equi- potential curves are drawn by the vertical translation of the curve cp (x> z, t) = 0. In the ice above the glacier bed cp > 0. Inside the water reservoir the water pressure is hydro- static and cp = 0. Water flows towards the water reservoir from high to low potentials. Fig. 3. A schemadc sec- tion of a glacier to illu- strate the relationship be- tween glacier surface and the shape of subglacial water reservoirs. a) Stable reservoir in a bed-depression beneath a dome. b) Water cupola beneath a surface depression. Mynd 3. Þversnið af jökli, sem sýnir samband milli lögunar yfirborðs og vatnsgeyma. a) Geymir i skál undir jökulbungu. b) Hvelfdur geymir undir dœld í jökulyfirborði. JÖKULL 25. ÁR 5

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