m + H mc mHCO~ mHCO~ (7) The bicarbonate concentration is higher in the residual snow than in the original snow, thus m//rc takes a negative value. However, bicarbonate concen- tration is lower in the meltwater than in the original snow, thus mjjmc takes a positive value. The bicarbon- ate concentrations in equations 6 and 7 can be written m terms of proton concentration using the equilibrium constants of Plummer and Busenberg (1982) assuming air saturation at the temperature of the pH measure- ments, the partial pressure of CO2 to be 10-3 5 bars and assuming activity to be equal to molality. Rewrit- mg equations 6 and 7 at 22° C and pluggingthe results into equation 5, yields mH+ = ( mH+ + /ÍQ-"'30 V mHt / 1Q-1130 V mHt 1Q-H.30 \ \ mHt )) ÍQ-11 30\\ (1 - Xm) + (8) Equation 8 can be solved for example for the pro- ton concentration of meltwater ni//rc which can be Iranslated to pH of meltwater assuming activity to be equal to molality. This tums out to be a second degree cquation with one real solution ZH± -b+y/b2 + 4XilO-H'3 2X„ where b is equal to (9) lO-n.3 jo-n.3 b = m„+ ---------------------Xmm + m mnt mH+ lO-n.3 + Xm----------m + (10) mH+ The solution of equation 9 is shown in Fig. 11 as a function of the mass fraction of the original snow melted, where the pH of the original snow is 5.45 and •+00 and the final pH of the partially melted snow that is left is in both cases 5.85. The upper curve in Fi§- 11 could represent core 1 (Fig. 5). The average PH of the frozen part of the 1987-1988 layer in core 1 is 5.45 but the average pH of the 1986-1987 layer Figure 11. The calculated pH (at 22 °C) of water produced by partial melting of snow is plotted versus the mass fraction of the original snow that has melted in the case where the pH of the original snow is 5.00 (the lower curve) and 5.45 (the upper curve) and the final pH of the remaining residual snow in both cases is 5.85. —Reiknað pH vatns, sem myndast við það að snjór bráðnar að hluta, er sýnt sem fall af massahluta bráðvatnsins. Þegar massahlutinn er 0 er ekkert bráðið en ef hann er 1 þá er allur snjórinn bráðinn. Neðri ferillinn lýsir sýrustigi bráðvatnsins þegar pH snœvar fyrir bráðnun er jafnt og 5,00 en sá efri þegar pH er jafnt og 5,45. Sýrustig snævar, eftir að hafa bráðnað að hluta er 5,85 í báðum tilfellum. is 5.85. Constraints on the mass fraction of the winter precipitation that melts in the summer can be found in Table 4.2 in Björnsson (1988). Bjömsson measured the mass balance of the ice drainage basin of Tungná in 1985-86. Below 1150 m.a.s.l. all of the winter precipitation melts, but above that there is a continuous decrease in summer melt with increased altitude. At 1300-1350 m.a.s.l. about 36% has melted, 18% at 1400-1450, 9% at 1500-1550, and 7% at 1600-1650 m.a.s.l. Core 1 was collected at 1680 m.a.s.l. (Fig. 2, Table II). Thus if the mass balance is similar to the one measured by Bjömsson (1988) one would expect the melt fraction for core 1 to be somewhat less than 10%. According to the upper curve in Fig. 11, the weighted average pH of the meltwater whose mass fraction of the original snow is less than 0.1, is below 4.4. In JÖKULL, No. 40, 1990 113

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