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Geological Survey Professional Paper 715—A
Combined Ice and Water Balances of Gulkana and Wolverine Glaciers, Alaska, and South Cascade Glacier, Washington, 1965 and 1966 Hydrologic Years |
1966 HYDROLOGIC YEAR
(continued)
GULKANA GLACIER
Field Program
Gulkana Glacier was visited in late September 1965, when preliminary ice-balance measurements were made at two sites (table 5). During the summer (May-September 1966) the snow balance was measured, an additional balance site established, a hut constructed, and a streamflow gaging station installed (pl. 5A). Continuous streamflow data, however, were not produced until almost the end of the hydrologic year, so none are reported here; nor are any continuous temperature or precipitation data available. These data will appear in reports covering subsequent hydrologic years.
TABLE 5.—Instrumentation at Gutkana Glacier during the 1966 hydrologic year
Climate
The weather during the 1966 hydrologic year at
several nearby low-altitude weather stations had no outstanding
variations from a normal pattern, and the glacier balance was apparently
in the normal range. The large new snow accumulation during August and
September 1966 occurred during the time when the maritime coastal
regions were receiving more than usual precipitation. One measurement
made on Gulkana Glacier on September 26, 1965, indicates that roughly
0.10 m water equivalent of new snow, the initial snow balance, 
0(s), was
present on the glacier at the beginning of the 1966 hydrologic year.
Ice Balance
The snowpack in the basin on May 18, 1966 (pl.
5B), averaged 0.82 m water equivalent (m(s), table 6). This was 5-10 times
more than the winter snowfall recorded at several weather stations in
the Copper River basin to the south and the Tanana River valley to the
north. The relation of late-winter snow balance to altitude (pl.
5C) cannot, however, be interpreted to be the same as the change
of precipitation with altitude. Some of the increase with altitude is
caused by storms which rain on the lower elevations but snow higher up.
In addition, a large part of the snow which falls high in Gulkana
Glacier basin is blown away by strong south winds; this snow either
evaporates or is redeposited on Canwell Glacier to the north. Little or
no snow is blown into Gulkana Basin by these same winds because no high
windblown mountains are present immediately to the windward south side
of the basin. The average snowpack density on May 18 was about 0.36
megagrams per cubic meter.
TABLE 6.—Snow and ice balances, Gulkana Glacier, 1966 hydrologic year
[Parameter values and errors in meters except where indicated, Date: Hydrologic year, Oct. 1, 1965 (t0), to sept, 30, 1966 (t1)]
| Glacier |
Basin |
Date | Term | Explanation | |||
| Value | Error | Value | Error | ||||
Parameters for annual mass balance | |||||||
| a |
0.06 | 0.19 | 0.03 | 0.15 | Hydrologic year | Annual balance | Net change in glacier mass from t0 to t1; approximately equal to the difference between precipitation as snow and melt-water runoff for one hydrologic year. |
Parameters relating annual and net mass balance | |||||||
| a(fi) |
-0.21 | .10 | -0.19 | .10 | Hydrologic year | Firn and ice annual balance | Change in mass of firn and ice from t0 to t1. |
| 0(s) |
.10 | .05 | .08 | .04 | Oct. 1, 1965 | Initial snow balance | New snow accumulated on summer surface (ss0) at t0. |
| 0(i) |
0 | 0 | Initial ice balance | Ice melt in the ablation area after t0 and before ice melt begins the following spring; measured by ablation stakes. | |||
| 1(s) |
.37 | .10 | .30 | .08 | Sept. 30, 1966 | Final snow balance | New snow accumulated on summer surface (ss1) at t1. |
| a(i) |
.76 | .12 | .57 | .10 | Hydrologic year | Annual ice balance | Ice and firn melt in the ablation area for the hydrologic year. |
| a(f) |
.55 | .10 | .38 | .08 | do | Annual firnification | New firn formed on the glacier from t0 to t1; not definable if snow melt continues after t1. |
Parameters for snow accumulation | |||||||
| m(s) |
1.00 | 0.15 | 0.82 | 0.15 | May 18, 1966 | Later-winter snow balance | Balance measured to the summer surface (ss0) in late winter or spring; measured in pits or by probing. |
Parameters for glacier dimensions | |||||||
| S | 121.8 | 0.2 | 31.6 | 0.2 | Sept. 30, 1966 | Area | Area of glaciers, excluding the ice-cored moraines. |
| AAR | 2.59 | 2.02 | 2.41 | 2.02 | do | Accumulation-area ratio | A rough index of annual balance, measured at time t1, neglecting new snow overlying ss1. |
| ELA | 1770 | 30 | do | Equilibrium-line altitude | Do. | ||
| δL | -44 | 10 | Hydrologic year | Advance or retreat | Average horizontal-distance change of terminus in direction of glacier flow. | ||
1Square kilometers. 2Dimensionless. | |||||||
The snowpack reached its maximum balance, x, about May 20,
1966, at the lowest point in the basin; maximum balance was probably
reached about July 15, 1966, high in the basin. Possibly the highest
areas accumulated snow continually throughout the year. About 55 percent
of the snowpack measured May 18 on the glaciers did not melt, and this
residual snow was identifiable as firn in September 1966. High in the
eastern cirques, summer avalanches and storms caused considerable
accumulation. Small patches of firn remained on the glacier at altitudes
as low as 1,600 m. New snow definitely began accumulating by August 15
at 1,940 m and by September 15, 1966, at 1,400 m.
Ablation of glacier ice began early in May 1966 from snowfree (windblown) morainal ridges low on the glacier (pl. 5A). The melting became most rapid in July and continued until the ice became fully snow covered in late September 1966 (pl. 5D). Ice ablation measurements were made on September 23, after the ice was snow covered. Some ablation of the previous year's firn occurred in July and August, and this is included as glacier-ice ablation. Near the glacier terminus, a maximum ablation of 4.0 m occurred on bare ice; however, a 10-20 cm layer of supraglacier moraine reduced the annual ice ablation locally to about 2.5 m. Isolated areas of ice ablation occurred up to an altitude of 2,300 m. The amount of glacier-ice ablation exceeded the formation of firn, so the annual firn and ice balance was -0.21 m (pl. 5E, table 6).
Heavy snowfall in August and September covered the
entire basin with new snow by September 20, 1966 (pl. 5D). From
measurements taken September 23, it is estimated that the basin had an
average final snow balance, 1(s), of 0.30 m at the end of the
hydrologic year. This heavy snow accumulation exceeded the initial snow
balance and more than made up for the basin's negative firn and ice
balance, a(fi), of -0.19 m; as a result the basin
gained 0.03 m storage, a, during the 1966 hydrologic year (table
6).
The continuous formation of kettle holes and the exposure of ice after mudflows indicates that ablation from the ice-cored moraine was occurring. The amount of melting (pl. 5E) was estimated to be greater than 1 m in localities having 20 percent bare ice exposed and 0.1 - 0.5 m where the ice is buried below alluvium and till.
The terminus of the glacier is stagnant and consists of nearly level ridges of ice. Ablation of some of this ice caused a terminal retreat of about 44 m. The glacier has retreated 530 m since 19S4 and about 2 km since 1910 (Reger, 1964, pl. 1), an average retreat rate of 36 m per year.
Precipitation and Runoff
The annual precipitation and runoff during the 1966 hydrologic year are estimated to be from 1.5 to 2 m on the basis of the data for snow and ice balance and on an estimate of 0.5 m of additional ungaged precipitation. The precipitation and runoff from the low forested regions of interior Alaska are only 10-20 percent of the estimated values for Gulkana Basin; therefore, the glacier-covered Alaska Range contributed an important part of the water runoff from the area.
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Last Updated: 28-Mar-2006