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Glacier Fluctuations and Climate in the Cordillera Blanca, Peru

Published online by Cambridge University Press:  20 January 2017

Georg Kaser ,
Alcides Ames  and
Marino Zamora
Georg Kaser
Affiliation:
Geographical Institute, University of Innsbruck,Innrain 52, A-6020 Innsbruck, Austria
Alcides Ames
Affiliation:
Hidrandina S.A., Glaciologia e Hidrologia,Jr. 28 de Julio 857, Huaraz (Ancash), Peru
Marino Zamora
Affiliation:
Hidrandina S.A., Glaciologia e Hidrologia,Jr. 28 de Julio 857, Huaraz (Ancash), Peru
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Abstract

With a total of 723 km2 of glaciers (1970) the Cordillera Blanca includes the largest glacier-covered area in the tropics. The climate is characterized by relatively large daily and small seasonal temperature variations as well as by a distinct succession between a dry (May–September) and a wet season (October–April). Since the early 1970s an ablation stake network has been installed on the tongues of the glaciers Uruashraju and Yanamarey. The determination of the equilibrium-line altitude at each end of a wet season was possible, showing a fair correlation with temperature, but not with the precipitation records of the nearby climatological station Querococha. Mean ablation rates at the lowest parts of the glacier tongues are markedly higher during the wet season than during the dry season. Reasons are presumably to be found in the seasonal variation of cloudiness and air moisture rates. Terminus variations of four glaciers in the Cordillera Blanca have been monitored since the early seventies, earlier positions are reconstructed back to 1948 by vertical air photographs. For the glaciers Uruashraju and Yanamarey the terminus positions of 1939 are known from an early map. The general retreat of glaciers in the Cordillera Blanca during the last five decades correlates with the global attitude of glaciers and especially with the attitude of glaciers in other tropical areas. Decreased recession rates with minor advances (1974–79 and 1985–86) are accompanied by lower annual temperatures and preceded and accompanied by years with relatively high annual precipitation sums.

Type
Research Article
Information
Annals of Glaciology , Volume 14 , 1990 , pp. 136 - 140
Copyright
Copyright © International Glaciological Society 1990

Introduction

With 722 glaciers covering a total area of 723 km2 (Reference AmesAmes and others, 1988; based on vertical infrared NASA air photographs from 1970) the Cordillera Blanca (8°30′–10°S and 77°50′ −77°10′W) includes the largest glacier-covered area in the tropics (Fig. 1). The earliest detailed glaciological information about the Cordillera Blanca is based on the research and resulting topographical maps of H. Kinzl who worked from 1932 in a number of scientific expeditions to the area (Borchers, Reference Borchers1935; Kinzl, Reference Kinzl1942, Reference Kinzl1949, Reference Kinzl1964). At least since then the glaciers have continuously receded. In the present paper the authors try to analyse glaciological and climatological data and to explain the recorded glacier retreat.

The climate in the Cordillera Blanca is characterized by relatively large daily and small seasonal temperature variations as well as by a distinct succession between dry (May–September) and wet seasons (October–April) (Fig. 2). Thus the mass accumulation on the glaciers occurs almost entirely during the wet season. Observations show that occasional snow cover on the tongues melts within a few days. Thus the mass accumulation occurs almost entirely in the upper part of the glaciers.

Fig. 1. The Cordillera Blanca and watershed of the Rio Santa catchment. Triangles indicate the chain of the highest peaks. The positions of Broggi, Uruashraju, Yanamarey and Gajap glaciers and the Querococha climatological station are shown. Glaciers are represented by shaded areas.

Two peculiarities affect the seasonal and topographical distribution of precipitation and thus also the glacial regime in the Cordillera Blanca:

Fig. 2. Mean monthly precipitation (1954–1987) and maximum mean and minimum temperatures (monthly means 1965–1987) at Querococha (3955 m).

  • (a) The oscillation of the cloud and precipitation belt of the Intertropical Convergence Zone (ITCZ) causes the seasonal distribution of precipitation.

  • (b) Due to the geological structure of the Cordillera Blanca the watershed of the Rio Santa catchment area lies a few kilometers east of the highest peaks (Fig. 1). The moist air masses brought by the ITCZ from the southeast overlap the watershed and therefore cause ample precipitation also in the high altitude, leeward catchment areas and glaciers of the Cordillera Blanca (Fliri, Reference Fliri1968).

Figures 3 and 4 show these processes and their effects schematically.

Mass Balance Records

Glaciers Uruashraju and Yanamarey

Since the early seventies an ablation stake network has been installed on Uruashraju and Yanamarey glaciers (Fig. 1). These are situated in the southern part of Cordillera Blanca. Both glaciers face southeast. Uruashraju covers an area of approximately 2.1 km2 between 4600 and 5700 m a.s.l., Yanamarey approximately 1.25 km2 between 4600 and 5200 m. Since 1975 the tongue has been calving into a small moraine-dammed lake. From 1980/81 the stakes were measured at the ends of both the wet and the dry season, yielding the seasonal net mass balances for these points. Following the definition of the mass balance year as extending from one entire glacier mass minimum to the next, the end of the dry season is the end of the mass balance year. For the years 1977/78 to 1979/80 it was possible to reconstruct the net balance amounts for the respective wet seasons.

To obtain a smoothed distribution of specific mass balance b with altitude z, mean values at 50 m steps in elevation were calculated. Three to 12 single values were used for each zone. The results in Figure 5 show that ablation occurs on the glacier tongues throughout the year.

Fig. 3. Idealized position of the Intertropical Convergence Zone (ITCZ) above South America in July and August (after Graf, Reference Graf1986) and schematic illustration of the dry season weather conditions in the Cordillera Blanca (CB).

Fig. 4. Idealized position of the Intertropical Convergence Zone (ITCZ) above South America from November to April (after Graf, Reference Graf1986) and schematic illustration of the wet season weather conditions in the Cordillera Blanca (CB).

Fig. 5. Variations in specific mass balance b with altitude z for the tongues of Uruashraju and Yanamarey glaciers. For most cases it was possible to subdivide the annual specific mass balance (W + D) into the seasonal balances of the wet (W) and the dry (D) season. Further explanations are given in the text.

Equilibrium-line altitude at the end of the wet season (ELAW)

The uppermost ablation stakes in a number of years were situated in the accumulation zone of the glaciers permitting determination of the ELAW. For other years ELAW values were obtained by graphical extrapolation. These extrapolations are rough for 1979/80 on both Uruashraju and Yanamarey, for 1982/83 and 1983/84 on Yanamarey and for 1986/87 on Uruashraju) (Fig. 5).

ELAW values are plotted for both glaciers in Figure 6, along with mean temperatures and precipitation sums for the respective wet seasons. Climatological data were recorded at station Querococha, situated at 3955 m a.s.l. 10 km from the Yanamarey glacier (Fig. 1). It is obvious that ELAWcorrelates with temperatures, but not with precipitation. Statistical analysis confirms a fairly high correlation coefficient r between a mean ELAW of both glaciers with the maximum temperatures (ELAW: tmax,W; r = 0.69), the mean temperatures (ELAW: tmean,W; r = 0.79 and the minimum temperatures (ELAW: tmin,W r = 0.71) whereas the correlation coefficient with the wet season precipitation sums is r = −0.09.

Highest accumulation occurs in the wet season but ablation is also large; the height of the equilibrium line is primarily dependent on the altitude of transition from snow to rain. Lack of records make it impossible to establish what happens in areas of accumulation, or to establish the entire mass balance of both glaciers.

Ablation during wet and dry seasons

A reconstruction of the equilibrium line at the end of the dry season and thus at the end of the entire mass balance year is, in the view of the authors, hardly possible due to absence of enough information. But it is possible to compare the specific mass balance of the wet season with the ones of the dry season for the lowest areas of both tongues. Table I shows data for altitudes between 4600 and 4650 m a.s.l. for both the glaciers.

Mean ablation rates on the glacier tongues are roughly a third higher in the wet season than in the dry. This fact leads to assumptions with regard to heat balance which have to remain speculative due to lack of energy balance investigations.

During the wet season, denser cloud cover and a higher air moisture rate might be the reasons for the fact that the energy flux due to longwave radiation and sensible heat flux play an important role. During the dry season this energy amount, which is available for melting, is smaller for the following reasons:

  1. Air masses are drier and cloud cover is less than in the wet season. This leads to higher amounts of nocturnal outgoing longwave radiation and therefore to lower temperatures of the ice surface (see minimum temperatures in Figure 2), which in the course of the day have to be heated up to melting point.

  2. The drier air causes higher evaporation rates but they equal only one seventh of the mass loss, which could melt in other processes requiring the same amount of energy (Kaser, Reference Kaser1983, 1986).

  3. High evaporation as shown by Hastenrath (Reference Hastenrath1978) at the Quelccaya Ice Cap in southern Peru together with the shortwave solar radiation causes heavy differential ablation (even “nieve penitentes”) and so a rougher, more porous ice surface. Such a ice surface seems to look whiter and thus points to a higher albedo, which reduces the energy absorbed.

Table I. Values of Mean Seasonal Net Ablation (bW and bD) for the 4600 to 4650 m Elevation step and for Uruashraju and Yanamarey Glaciers in Meters Water Equivalent. Values are corrected to represent the exact number of days: 212 for the wet and 153 for the dry season. W: wet season; D: dry season.

Fig. 6. The altitude of the equilibrium line at the end of the wet season ELAW. Circles, Uruashraju; triangles, Yanamarey. Full signs indicate values based on measurements, open signs values obtained by graphical extrapolation from Figure 5. Arrows indicate the uncertainty of rough extrapolations. The middle and lower part of the figure show mean temperatures and precipitation sums for the respective wet seasons, recorded at Querococha.

The data series are too short for a statistical analysis of the coherence between ablation amounts, temperature and precipitation during the dry season. Figure 7 shows the tendency that higher temperatures and less precipitation lead to more ablation, while lower temperatures and more precipitation lead to less ablation. Yearly changes of the amount of ablation during the dry season are the same on both glacier tongues.

Glacier Terminus Variations

Figure 8 shows variations in the terminus position οf four glaciers in the southern Cordillera Blanca. The position of these glaciers is indicated in Figure 1. Ground measurements were begun in 1968 and 1972 respectively; earlier positions were determined from vertical aerial photographs. For Uruashraju and Yanamarey glaciers it was possible to reconstruct additional positions for 1939 from the map “Cordillera Blanca, parte sur”, 1:100 000 (Kinzl, Reference Kinzl1942). Due to the scale, accuracy of these data is low.

Figure 8 shows the general retreat of the four glaciers in the last five decades. Detailed records made since 1972 show a halt in the general rate of retreat with minor advances in both Yanamarey and Uruashraju between 1974 and 1979. Between 1985 and 1986 rates slowed down again.

The amount and density of available data do not permit a serious statistical analysis in comparison with climatological records. However, the plot in Figure 8 indicates that periods with decreased recession rates are accompanied by lower annual temperatures, and preceded and accompanied by years with relatively high annual precipitation sums. The changes in terminus recession rates occur approximately four years after the beginning of the periods with higher precipitation.

Lower temperatures principally reduce ablation at the tongue and directly influence the terminus position, whereas increased accumulation amounts have an effect due only to glacial dynamics. The attitude of Yanamarey may be influenced due to its calving into a moraine-dammed lake since the mid-1970s. A small lake in front of Uruashraju terminus was observed for the first time in May 1989.

Conclusions

The general retreat of glaciers in the Cordillera Blanca during the last five decades correlates with global changes in other glaciers, and especially in those of tropical areas (Patzelt, Reference Patzelt1987). Decreased recession rates during the second part of the 1970s contrast with the continuously strong recession of East African glaciers (Hastenrath, Reference Hastenrath1984; Reference Patzelt, Schneider and MoserPatzelt and others, 1985), but correlate with the general advances in the Alps and the North American cordilleras (Patzelt, Reference Patzelt1987).

Fig. 7. Dry season mean net ablation values for the 4600–4650 m elevation steps of Uruashraju (circles) and Yanamarey (triangles), and mean temperatures and precipitation sums for the respective dry seasons, recorded at Querococha.

Fig. 8. Terminus variations of Gajap (G), Uruashraju (U), Yanamarey (Y) and Broggi (B) glaciers, starting from a common reference point in 1948. For Uruashraju and Yanamarey the terminus positions of 1939 were reconstructed. In the middle, annual mean temperatures are plotted, while the lowest graph shows the annual amounts of precipitation with an overlying five-year running mean curve. The broken line indicates the long-term average of precipitation. Climatological data were recorded at Querococha.

While the strong retreat of Lewis Glacier on Mount Kenya is thought to be caused by relatively low precipitation, variations on the Cordillera Blanca glaciers correlate with both precipitation and air temperatures. Variations in air temperatures in the tropics are in principle not dependent on the dynamics of different air masses but, almost without exception, are controlled by local energy balance. Both seasonal and long-term variations of energy balance are caused principally by variation of atmospheric moisture and cloudiness, which in the tropics are linked to intensity and pattern of the ITCZ.

Due to the lack of accumulation records, knowledge of mass balance of glaciers in the Cordillera Blanca has to be limited to the ablation zone. The generally steep and rugged accumulation areas are often threatened by ice avalanches and therefore usually inaccessible. The glacial regime in the Cordillera Blanca is generally indicated by the occurrence of ablation during the entire year and of accumulation almost exclusively during the wet season and in the firn area. Ablation rates are markedly higher during the wet season.

Analysis of the available glaciological and climatological data permit a number of conclusions. Detailed knowledge of the energy budget and questions relating to mass accumulation have to remain open.

References

Ames, Α and seven others. 1988. Inventario de glaciares del Peru. Primera parte. Huaraz, Hidrandina S.A. (Unidad de Glaciologia e Hydrologia 171.)Google Scholar
Borchers, P 1935. Die Weisse Kordillere. Berlin, Verlag Scherl. Google Scholar
Fliri, F 1968. Beiträge zur Hydrologie und Glaziologie der Cordillera Blanca (Peru). Veröff. Univ. Innsbruck, Alpenkund. Stud., 1, 2552.Google Scholar
Graf, K 1986. Klima und Vegetationsgeographie der Anden. Grundzüge Südamerikas und pollenanalytische Spezialuntersuchungen Boliviens. Zürich, Universität Zürich. (Physische Geographie.)Google Scholar
Hastenrath, S 1978. Heat-budget measurements on the Quelccaya ice cap, Peruvian Andes. J. Glaciol., 20(82), 8597.Google Scholar
Hastenrath, S 1984. The glaciers of equatorial East Africa. Dordrecht, etc., D. Reidel Publishing Company. Google Scholar
Hidrandina, S.A Unpublished. Glaciological and climatological data. Google Scholar
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Figure 0

Fig. 1. The Cordillera Blanca and watershed of the Rio Santa catchment. Triangles indicate the chain of the highest peaks. The positions of Broggi, Uruashraju, Yanamarey and Gajap glaciers and the Querococha climatological station are shown. Glaciers are represented by shaded areas.

Figure 1

Fig. 2. Mean monthly precipitation (1954–1987) and maximum mean and minimum temperatures (monthly means 1965–1987) at Querococha (3955 m).

Figure 2

Fig. 3. Idealized position of the Intertropical Convergence Zone (ITCZ) above South America in July and August (after Graf, 1986) and schematic illustration of the dry season weather conditions in the Cordillera Blanca (CB).

Figure 3

Fig. 4. Idealized position of the Intertropical Convergence Zone (ITCZ) above South America from November to April (after Graf, 1986) and schematic illustration of the wet season weather conditions in the Cordillera Blanca (CB).

Figure 4

Fig. 5. Variations in specific mass balance b with altitude z for the tongues of Uruashraju and Yanamarey glaciers. For most cases it was possible to subdivide the annual specific mass balance (W + D) into the seasonal balances of the wet (W) and the dry (D) season. Further explanations are given in the text.

Figure 5

Table I. Values of Mean Seasonal Net Ablation (bW and bD) for the 4600 to 4650 m Elevation step and for Uruashraju and Yanamarey Glaciers in Meters Water Equivalent. Values are corrected to represent the exact number of days: 212 for the wet and 153 for the dry season. W: wet season; D: dry season.

Figure 6

Fig. 6. The altitude of the equilibrium line at the end of the wet season ELAW. Circles, Uruashraju; triangles, Yanamarey. Full signs indicate values based on measurements, open signs values obtained by graphical extrapolation from Figure 5. Arrows indicate the uncertainty of rough extrapolations. The middle and lower part of the figure show mean temperatures and precipitation sums for the respective wet seasons, recorded at Querococha.

Figure 7

Fig. 7. Dry season mean net ablation values for the 4600–4650 m elevation steps of Uruashraju (circles) and Yanamarey (triangles), and mean temperatures and precipitation sums for the respective dry seasons, recorded at Querococha.

Figure 8

Fig. 8. Terminus variations of Gajap (G), Uruashraju (U), Yanamarey (Y) and Broggi (B) glaciers, starting from a common reference point in 1948. For Uruashraju and Yanamarey the terminus positions of 1939 were reconstructed. In the middle, annual mean temperatures are plotted, while the lowest graph shows the annual amounts of precipitation with an overlying five-year running mean curve. The broken line indicates the long-term average of precipitation. Climatological data were recorded at Querococha.