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Temperate glacier time response from field data

Published online by Cambridge University Press:  20 January 2017

D. M. McClung
Affiliation:
Departments of Civil Engineering and Geography, University of British Columbia, Vancouver, British Columbia V6T 1Z4, Canada
Richard L. Armstrong
Affiliation:
Cooperative Institute for Research in Environmental Sciences, University of Colorado, Boulder, Colorado 80309, U.S.A
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Abstract

The relationship of glacier response due to mass-balance changes is of fundamental importance when climate variations are to be understood. In this paper, two aspects of the problem are analyzed from field data: (1) advance/retreat of the glacier terminus due to changes in mass balance, and (2) cross-correlation of mass-balance data from two glaciers in the same climate zone. The results show: (1) the terminus can respond quickly in accordance with expected minimum time-scale, and (2) two glaciers in the same general climate zone may have very different yearly mass balance and advance/retreat behaviour. This latter result indicates the importance of local climate variations.

Type
Research Article
Copyright
Copyright © International Glaciological Society 1993

Introduction

Field observations and measurements indicate that temperate alpine glaciers are sensitive indicators of climate. In particular, advance and retreat are governed by changes in mass balance. On a global scale, it is likely along with variability of Arctic sea ice, that glaciological evidence for global climate change will appear first with respect to advance and retreat of temperate glaciers. Reference Jóhannesson, Raymond, Waddington and OerlemansJóhannesson and others (1989a, Reference Jóhannesson, Raymond and Waddingtonb) presented a simple theory for time response of advance/retreat due to mass-balance changes based only on volume change caused by mass-balance perturbations. In this paper, the theory of Jóhannesson and others is applied by a time-series analysis of field measurements. In particular, field measurements of mass balance and terminus position of Blue Glacier reported by Reference Armstrong and OerlemansArmstrong (1989) and Reference SpicerSpicer (1989) are used. The results show agreement with the theory within an order of magnitude.

An additional aspect of the problem is explored by a time-series analysis of mass-balance data for Blue Glacier and South Cascade Glacier (Reference Krimmel and OerlemansKrimmel, 1989). Both of these glaciers are in the same general maritime climate zone but separated by 200 km. However, their mass balance and advance/retreat history over the past 30 years appear radically different (Reference Armstrong and OerlemansArmstrong, 1989). Cross-correlation of time-series records of mass balance shows that the mass balances are essentially uncorrected for a given year but there is a significant correlation with a lag of 3 years. However, it is unlikely that this latter result is of substantial importance.

Theory

Reference Jóhannesson, Raymond, Waddington and OerlemansJóhannesson and others (1989a, Reference Jóhannesson, Raymond and Waddingtonb) derived simple order-of-magnitude relationships to illustate the time- and spacedependent response of temperate (non-surge type) glaciers to mass-balance changes. Their theory essentially involves relating the total rate of change of glacier mass per unit time (dM/dt) to Qb : the balance flux evaluated at the glacier terminus. At the terminus, Qb is represented by (Reference Raymond and ColbeckRaymond, 1980):

(1)

In Equation (1), b is net mass balance, A is horizontal area of the glacier above the terminus and ρ is ice density, and the integral is taken over the entire glacier area above the terminus.

By assuming that small changes in glacier volume (due to mass-balance changes) result primarily in area changes at the terminus by extension/retreat, Reference Jóhannesson, Raymond, Waddington and OerlemansJóhannesson and others (1989a) showed that the minimum (order-of-magnitude) time-scale for response contained in Equation (1) is:

(2)

In Equation (2), Η is a thickness scale for the glacier (e.g. average of maximum glacier thickness (m)) and bt is an index of ablation rate at the terminus (m a−1). Readers are referred to Jϳhannesson and others (1989a,b) for a more complete discussion of the implications of Equation (2).

Analysis

The area-averaged net mass balance of Blue Glacier for the period 1956–86 is shown in Figure 1 (Reference Armstrong and OerlemansArmstrong, 1989). The terminus position recorded relative to a point below the glacier which the terminus reached in 1938 (Reference SpicerSpicer, 1989) is shown in Figure 2 for the same period. Note, therefore, that positive increase in terminus position signifies terminus retreat.

Fig. 1. Area-averaged net mass balance of Blue Glacier (m water) as a function of time. Data from Reference Armstrong and OerlemansArmstrong (1989)

Fig. 2. Terminus position of Blue Glacier in meters from the 1938 position below the glacier. A terminus-position decrease means glacier advance. Data adapted from Reference SpicerSpicer (1989).

A time-series analysis was performed for the data depicted in Figures 1 and 2 by calculation of the cross-correlation of the series. Analysis of the raw data showed that the highest correlation coefficients occurred for lags of 7–12 years where lag means response time for advance of the terminus corresponding to positive increase in mass balance. These correlation coefficients varied between −0.24 and −0.33 (lag of 10 years). Negative coefficients were obtained, since the 1938 reference point is below the present terminus: when the terminus advances, distance from the reference point decreases (See Fig. 2). For the highest correlation −0.33 (at 10 years’ lag), the standard error is 0.22. This lag was the most significant correlation between the two series; it had the highest correlation coefficient and highest ratio of correlation coefficient to standard error (1.5).

Since terminus fluctuations represent a time-integrated response, the mass-balance data were smoothed over a suitable time-scale in order to compare cross-correlations for two series with similar time-scales of fluctuations. Figure 3 shows cross-correlation of mass balance with terminus position with mass-balance data smoothed (using moving averages) over a time period of 6 years. This smoothing period gave optimum correlation between the two series: other smoothing time periods between 2 and 10 years (and greater) showed lower values and less significance for the correlation coefficients. The analysis in Figure 3 (and that of the raw data) shows that the terminus lags positive mass-balance input by a time-scale of about 10 years. For all the values of correlation coefficients plotted in Figure 3, only those with lags between 7 and 11 years equal or exceed two standard errors in the analysis. The positive correlation coefficients for lags of −10 to −5 years are not significant, since they are comparable to the noise (one standard error) in the analysis.

Fig. 3. Cross-correlation of Blue Glacier mass balance with terminus position. Mass-balance data in Figure 1 were smoothed over a time-scale of 6 years before the analysis was performed.

For Blue Glacier, a relevant thickness scale is about 100–200 m (Reference Meier, Kamb, Allen and SharpMeier and others, 1974) with ablation rates there of about 3–5 m a−1 (Reference Armstrong and OerlemansArmstrong, 1989). From Equation (2), this gives a minimum time-scale of about 20 years which is in rough agreement with the analysis. Mass-balance data from Blue Glacier are not available for much more than about 30 years, so the possibility of longer time-scale interactions cannot be determined.

Mass-Balance Comparisons

Mass-balance data (Reference Krimmel and OerlemansKrimmel, 1989) from South Cascade Glacier are shown in Figure 4. South Cascade Glacier is the only other glacier (besides Blue Glacier) in the northwestern United States (Alaska excluded) with a long-term mass-balance record. During the period 1958–85, South Cascade Glacier lost about 10 m water equivalent averaged over the glacier surface (see Reference Krimmel and OerlemansKrimmel (1989) for presentation of data and discussion of accuracy) with a terminus-retreat distance near 400 m. During the same period, Blue Glacier had a slightly positive mass balance and advance of about 150 m. Therefore, there are significant differences in the mass-balance behaviour of these glaciers even though they are in the same general maritime climate zone and they occupy nearly the same altitude zones. Measurement errors for Blue Glacier are ±10–15% for ice ablation and ±10–20% for residual accumulation (Reference Armstrong and OerlemansArmstrong, 1989).

Fig. 4. Area-averaged net mass balance of South Cascade Glacier (m water) as a function of time. Data from Reference Krimmel and OerlemansKrimmel (1989).

In Figure 5, mass-balance data from Blue Glacier (Fig. 1) and South Cascade Glacier (Fig. 4) are cross-correlated as a function of time lag in years. Analysis showed that the cross-correlations are significant only at lags of −3 years (correlation of 0.55, standard error 0.20) and −5 years (correlation 0.40, standard error 0.20). These comparisons add to the differences between the two glaciers; not only are the mass-balance and terminus histories different over the 30 years’ comparison, individual (zero-lag) yearly balances do not seem to correlate either.

Fig. 5. Cross-correlation of mass-balance data from Blue Glacier and South Cascade Glacier (Figs 1 and 4).

Discussion

A time-series analysis of terminus advance and retreat for Blue Glacier indicates that positive mass balances can cause terminus advance in about a 10 year time-scale. This result is in rough agreement with the theory of Johannesson and others (1989a, b) that a time-scale on the ordçr of 10–20 years is possible for minimum response. This result also agrees with common field observations that advance and retreat of temperate (non-surge) glaciers can be rapid and of the same order as the data and theory indicated. Due to the short length of the time series, it is not possible to comment, from these measurements, on possible response times greater than 30 years.

One possible complication with respect to evaluation of the response time of Blue Glacier is the complexity of the geometry of the glacier terminus (Reference SpicerSpicer, 1989). However, the order-of-magnitude theory applied here makes this aspect of the problem beyond the scope of the present paper.

Comparison of mass-balance histories of Blue Glacier and South Cascade Glacier indicates that yearly balances do not correlate. At zero lag, the cross-correlation gave a correlation coefficient of 0.092 (standard error 0.192) which is not close to being significant. This result further enhances the differences between the mass balance and advance/retreat histories of these glaciers. Together, the results may show that a sample size of two is too small to characterize climate implications from glacier fluctuations in a general area; specifics of local climate are important. Since Blue Glacier is significantly closer to the moisture source (Pacific Ocean) than South Cascade Glacier, the local climate may differ significantly from that of South Cascade Glacier. Even though South Cascade Glacier is in a drier area than Blue Glacier, both glaciers usually intercept the same storms and the general weather patterns are similar. Therefore, one might expect mass balances to cross-correlate on a yearly basis. Apparently, local climate differences dominate over general climate in this case. These results are in contrast to data reported by Reference Schmok and ClarkeSchmok and Clarke (1990) from Place and Sentinel Glaciers in the Coast Mountains of southern British Columbia. A cross-correlation analysis (24 years of records) of net-balance data from these glaciers gave a correlation coefficient of 0.84 at zero lag with a standard error of 0.204; a highly significant result. Place and Sentinel Glaciers are separated by only 65 km in a north-south configuration; apparently, in this case the local climate is similar enough to produce good correlation in mass balance.

References

Armstrong, R.L. 1989. Mass balance history of Blue Glacier, Washington, USA. In Oerlemans, J., ed. Glacier fluctuations and climatic change. Dordrecht, Kluwer Academic Publishers, 183192.Google Scholar
Jóhannesson, T., Raymond, C.F. and Waddington, E.D. 1989a. A simple method for determining the response time of glaciers. In Oerlemans, J., ed. Glacier fluctuations and climatic change. Dordrecht, Kluwer Academic Publishers, 343352.Google Scholar
Jóhannesson, T., Raymond, C.F. and Waddington, E.D. 1989b. Time-scale for adjustment of glaciers to changes in mass balance. J. Glacial., 35(121), 355369.Google Scholar
Krimmel, R.M. 1989. Mass balance and volume of South Cascade Glacier, Washington, 1958–1985. In Oerlemans, J. ed. Glacier fluctuations and climatic change. Dordrecht, Kluwer Academic Publishers, 193206.Google Scholar
Meier, M.F., Kamb, W.B., Allen, C.R. and Sharp, R.P. 1974. Flow of Blue Glacier, Olympic Mountains, Washington, U.S.A. J. Glacial., 13(68), 187212.Google Scholar
Raymond, C.F. 1980. Temperate valley glaciers. In Colbeck, S. C. ed. Dynamics of snow and ice masses. New York, Academic Press, 79139.Google Scholar
Schmok, J. and Clarke, G. K. C. 1990. Mass-balance, geodetic and photographic surveys of Sentinel, Place and Helm glaciers: 1989 balance year. Ottawa, Environment Canada. National Hydrology Research Institute.Google Scholar
Spicer, R.C. 1989. Recent variations of Blue Glacier, Olympic Mountains, Washington, U.S.A. Arct. Alp. Res., 21(1), 121.Google Scholar
Figure 0

Fig. 1. Area-averaged net mass balance of Blue Glacier (m water) as a function of time. Data from Armstrong (1989)

Figure 1

Fig. 2. Terminus position of Blue Glacier in meters from the 1938 position below the glacier. A terminus-position decrease means glacier advance. Data adapted from Spicer (1989).

Figure 2

Fig. 3. Cross-correlation of Blue Glacier mass balance with terminus position. Mass-balance data in Figure 1 were smoothed over a time-scale of 6 years before the analysis was performed.

Figure 3

Fig. 4. Area-averaged net mass balance of South Cascade Glacier (m water) as a function of time. Data from Krimmel (1989).

Figure 4

Fig. 5. Cross-correlation of mass-balance data from Blue Glacier and South Cascade Glacier (Figs 1 and 4).