tion between the size of the open waters and meteorological and hydrological factors. The most important parameters seem to be the heat loss and the river discharge. Direct observations of the rate of heat loss from rivers are very limited as yet. We have considered three methods for such observations. With the first method the mass of ice in an ice jam is compared to calculated ice produc- tion. In 1965 the volume of an ice jam below Thjofafoss Falls (Burfell ice jam) in Thjorsa River was determined with photogrammetric methods on Febr. 23 and March 27. The in- crease in ice volume during this period was 19 ± 1 million cubic metres. The mean water equivalent of the ice jam is not known but on the surface it was 0.5—0.6. The measured in- crease in volume occurred in the period March 18—27 and there was no discharge of ice from the downstream end of the jam in this period. The total discharge of the river was 124 million cubic metres March 18—27. The calculated total ice production in the open water area upstream from the jam during this period was 15 million metric tons and it is estimated that about 13 million tons reached the jam. To bring this into agreement with the measured increase in volume the mean water equivalent of the jam must be 0.65—0.72 which is rather high but not quite unreasonable as the major part of the jam is dry and the thickness up to 15 metres. With the second method the river tempera- ture is measured in successive sections when the river is in a state of cooling and the heat loss is calculated from equation (18). This method has been tried in Thjorsa River but has not been sucessful as yet. The diffi- culties arise from the fact that there are com- paratively great temperature differences in the same cross section and there are some practical obstacles to obtain cross-sectional means. The Thjorsa River is wide and shallow where the temperature measurements were made and the temperature changes in these reaches can be very rapid as is seen from the following example from Oct. 13—14 1967. The river width is about 400 m and the depth 0.5 m, almost even in a reach of several kilometres. The discharge was 177 m3 sec-1. 368 JÖKULL 18. ÁR Time ‘w N vo ew ea hours °C 0-8 °C m sec-1 mb mb 18 1.09 1.0 1.5 11.5 6.7 5.3 19 0.98 1.2 1.1 10.9 6.5 5.2 20 0.81 2.0 0.9 12.9 6.4 5.0 21 0.60 2.7 0.8 11.9 6.3 5.0 22 0.38 2.3 0.6 12.8 6.2 5.0 23 0.17 1.3 0.2 12.6 6.1 4.8 24 0.0 1.0 -0.1 11.7 6.1 4.5 01 0.0 Here N, ta, V6, ew and ea are hourly means. The water temperature was zero at 2350 hours. It is interesting that in this example the air temperature is a little higher than the water temperature and accordingly there is a slight heat gain by convection but the heat loss by radiation and evaporation is many times higher. The water was slightly supercooled (tw rz -^0.01 °C) at about the same time as the air tempera- ture was down to 0 °C and frazil ice produc- tion had started. The third method consists in measuring the frazil ice discharge in successive sections of the river and obtain the heat loss from the open water area from the increase in frazil ice dis- charge. This would be the most rational ap- proach where the heat loss formulas are used for calculations of ice production as it is likely that the heat loss is affected by clusters of frazil ice floating on the surface. An ice dis- charge gauge based on the fact that the elec- trical conductivity of the ice-water mixture is a function of the ratio between ice volume and total volume of the mixture has been constructed by Mr. Björn Kristinsson, Elec- tronics, Reykjavik, but it has been on the ex- perimental stage up to now. CONCLUDING REMARKS Calculations of heat loss from a river sur- face and frazil ice production on the basis of meteorological observations are possible, pro-

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