Evaporation and convection The transfer of water vapour and sensible heat frorn a water surface to the atmosphere is analogous to the heat transfer in a turbulent river, provided the wind velocity is substantial. fn a thin layer near the surface the transfer is effected by molecular diffusion but higher up in the wind turbulent diffusion is prevail- ing. The diffusion equations are analogous to (3) or (4) but instead of cT there we have now: for convection: cp 0, where cp is the speci- fic heat of air at constant pressure and 0 the potential temperature; for evaporation: q, the specific humidity. The use of 0 and q, rather than other expres- sions for the temperature and humidity, is preferred because they are conservative with respect to dry-adiabatic motions (Haltiner and Martin 1957). Taking the x-axis in the wind direction and neglecting lateral diffusion the diffusion equa- tion for evaporation for the steady state be- comes 3(vq) J_a_ /K J3(vq) \ 3x 3z \ E 3z / (21) where y is the specific weight of air. The eddy-diffusion coefficients for evapora- tion, Ke, and convection, Kn, are functions of the height above the ground, wind velocity, the stability of the air etc. The coefficients are of the same order of magnitude as the coefficient for transfer of momentum, the eddy viscosity, Kj,. From the phenomenological turbulence theories an expression for KM can be obtained. (corresponding to (7)) but KE and KH can not be derived in a corresponding way. The simp- lest hypothesis is to assume Ke = KH = Km. With this and certain other assumptions Snt- ton (1953) has solved the equation (21) for an area which is infinite across wind and finite down wind and the wind direction is per- pendicular to the area. He uses a power law for the wind profile and an expression for KM which is derived on basis of statistical theory and mixing length theory. Sutton’s solution can be written E = constant ■ (qw — qa) vz° ,'s x0°-88 (22) where E is the total rate of evaporation per unit of cross wind length, x0 is the down wind dimension of the area, vz is the wind velocity at height z, qw is the specific humidity at the water surface and qa is the specific humidity of the air. It should by noted that E is not directly proportional to the area of the water surface. The relation (22) is in good agreement with laboratory experiments and observations in the field (Sutton 1953). The relation (22) is valid for a smooth surface but Sutton states that a virtually identical expression is obtained for a rough surface. It is to be expected that a relation similar to (22) is valid for evapora- tion from rivers. In practical cases the wind direction is however more or less variable and besides it would be complicated to include the river width in computations. The assumption of the equality of the dif- fusion coefficients needs a closer consideration. According to Sutton (1953) KH > KB = KM in unstable conditions and KH = KB > KM in stable conditions. When we are concerned with heat loss from open water during frost it is thus possible that the ratio KE/KH is a func- tion of the difference Tw — Ta, where Tw and Ta are the temperatures of the water and the air. Undoubtedly the wind structure is also significant. Smith (1951) has shown that con- tinuous records of the wind direction can be used as a basis for classification of the turbul- ence of the air. It seems worth-while to in- vestigate if there is a correlation between KE/ ICH and Smith’s types of turbulence as con- tinuous records of wind direction are readily obtainable. For comparison of the rate of lieat loss by evaporation and convection and to arrive at some approximate formulas we shall study the simplest case: the steady state over infinite water surface, assuming that KB = KH = KM. In this case the rate of heat loss per unit area by evaporation is = <*»> JÖKULL 18. ÁR 365

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