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Glacioclimatological features in the Tanggula mountains, China

Published online by Cambridge University Press:  20 January 2017

Ding Yongjian
Affiliation:
Lanzhou Institute of Glaciology and Geocryology, Academia Sinica, Lanzhou 730000, China
Li Zhongqin
Affiliation:
Lanzhou Institute of Glaciology and Geocryology, Academia Sinica, Lanzhou 730000, China
Liu Shiyin
Affiliation:
Lanzhou Institute of Glaciology and Geocryology, Academia Sinica, Lanzhou 730000, China
Yu Xinzhi
Affiliation:
Lanzhou Institute of Glaciology and Geocryology, Academia Sinica, Lanzhou 730000, China
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Abstract

Air temperature and precipitation data have been obtained from the Geladandong region at the headwaters of the Yangtze River. At the equilibrium line altitude of the glaciers, mean annual and summer air temperatures are –10 to –12.0°C and 1.0 to –1.0°C, respectively. Accumulation on the glaciers on the south side of the Tanggula mountains depends mainly on water vapour transported from the south and southeast. The moisture source for the glaciers on the north side is from the east. Precipitation increases with altitude in the glaciated areas. An estimated annual accumulation in the firn areas is about 400 to 600 mm of water equivalent. The Geladandon region has a cold, dry climate and the glaciers in the region can be classified as continental. The present climatic conditions result in a negative mass budget for most glaciers.

Type
Research Article
Copyright
Copyright © International Glaciological Society 1992

Introduction

The Yangtze River rises in the highest part of the Tanggula mountains in the vicinity of Geladandong mountain (Fig. 1). The region contains the principal concentration of glaciers in the interior of Qinghai-Xizhang Plateau. Reference LinyuanZhang (1981) discussed the distribution and morphological features of the present glaciers and the palaeoglaciological conditions in this region. Up to now, however, there has been little information about the climatic conditions controlling the glacierization and its potential changes. This paper provides an analysis of climate data in relation to the present state of the glaciers.

Fig. 1. Location of the research region. Numbers 1–12 also refer to Table 4.

Table 1. Vertical temperature gradients in °C 100 m−1 from ground to 500 mbar on the south and north sides of the Tanggula mountains (1965–80)

Table 2. Air temperature in °C in the Geladandong area (1960–80)

Table 3. Mean monthly air temperature, in °C, at mean ELA and mean terminal altitude (TAG) in various glacier systems of the Tanggula mountains (1960–80)*

Table 4. Air temperature, in °C, at ELA in various glacier systems of China (Reference Yafeng, Maohuan and BinghuiShi and others, 1988)

Air Temperature In The Glacier Areas

Direct measurements of air temperature in the glaciated areas have not been made. Air temperature was calculated by interpolation, based on data from meteorological stations around the glacierized areas. Three factors, altitude, longitude and latitude, were taken into consideration. In addition, a local factor must be included when air temperature over glaciers is estimated. The following method was used. First, the vertical air temperature gradient (VTG) was calculated on both sides of the Tanggula mountains, based on radiosonde measurements at meteorological stations (Table 1). The mean summer (June–August) VTG is about 0.6°C 100 m−1. The mean annual VTG is between 0.47 and 0.46°C 100 m−1. After the VTGs were determined, air temperatures at various altitudes were estimated over every surface and radiosonde station around the glacierized areas. Figure 2 shows the air temperatures at 4500 m a.s.l., estimated using the VTG. Smooth isotherms, consistent with the stations, were drawn to represent the geographical variation of mean summer and mean annual air temperature. Both mean summer and mean annual air temperature tend to decrease from the southeast toward the northwest.

Fig. 2. Temperature distribution at 4500 m a.s.l. in °C: (a) mean summer air temperature (b) mean annual air temperature. Numbers 1–8 also refer to Table 2.

The altitude of glaciers is generally above 4500 m a.s.l., but air temperature at any altitude on a glacier surface can be estimated from Figure 2, using the VTGs. In an alpine region there may be local variations that are difficult to predict. However, a drop in air temperature is expected over a glacier which can be estimated from the size of the glacier, using empirical formulae (Reference Kotlyakov and KrenkeKotlyakov and Krenke, 1982; Reference ZhongyuanBai, 1989). Air temperatures above some of the largest glaciers of the Geladandong area, estimated by these means, are given in Table 2. The results indicate that air temperature is low in the Geladandong region. Mean annual air temperature at the ELA is between –12.0 and –10.0°C and mean summer air temperature is between –1.0 and 1.0°C.

Air temperatures in other glacier systems of the Tanggula mountains have also been calculated using this method (Table 3). The mean terminal altitudes in the Geladandong, mid-Tanggula and Bujarkyagri areas are 5330, 5250 and 4700 m a.s.l. and the mean ELAs 5750, 5500 and 5350 m a.s.l., respectively. Air temperatures at the sites of these glaciers decrease northwestward both because of an increase in altitude of the glaciers in that direction and because of the regional trend of air temperature (Fig. 2). The especially low air temperatures in the glacierized area of Geladandong occur because of the location of this area at the northwest end of the range.

In comparison with air temperatures in various other glacier systems of China (Table 4), air temperatures in the Geladandong area are similar to those in areas of polar-continental glaciers. This indicates that the climate in the glacierized area of the Geladandong is cold and dry.

Sources of Water Vapour

Its interior location on the plateau causes the Geladandong area to be very dry. Precipitation in the Tanggula mountains is affected by the plateau summer monsoon (Reference Jijun and BenxingLi and others, 1986). Water vapour can reach the south side of the Tanggula mountains by two paths. One is the south and southwest path, through which water vapour moves northeastwards from northern India along a corridor between Zhong and Tingri (Fig. 1) to converge between Baingion and Amdo (Fig. 2) (Reference Qan and ChenQan and Chen, 1984). The other is the southeast path, through which humid air from the Bay of Bengal and the South China Sea is transported by south-easterly or southerly winds through the valleys of the Nujiang, Lancang and Yangtze Rivers, or along the gorges cutting through the Himalaya mountains, to reach the southwestern part of Qinghai Province (Reference ChengCheng, 1984) (Fig. 1). According to wind data recorded aloft along the south side of the Tanggula mountains there is an obvious difference in the wind frequency in January and July (Fig. 3). The south and southeasterly winds are predominant during the monsoon period in summer on the south side of the Tanggula mountains. However, on the north side easterly winds are predominant in summer. It can be inferred that water vapour on the north side probably comes from the east during summer. Humid air can be transported to the glacierized areas of the north side along the eastern valleys.

Fig. 3. Relative frequency of wind directions at 5000 m a.s.l. on both sides of the Tanggula mountains (1960–80). (a) and (b), south side; (c) and (d), north side.

The total area of glaciers on each side of the Tanggula mountains is about 2080 km2, of which 53% is on the north side and 47% on the south side. Therefore, the easterly path must be equally as effective as the southern one. This is also indicated by precipitation at lower altitudes, measured at weather stations on both sides of the range.

Precipitation In The Glacier Area

Because it is affected by the plateau summer monsoon, summer precipitation predominates on both sides of the Tanggula mountains (Fig. 4). Precipitation between June and August is about 70% of the annual precipitation. The highest precipitation rate occurs in July. Precipitation in the east is larger than in the west. On the south side, for example, annual precipitation at Sogxian Station (Fig. 2) is 572.6 mm, but at Nagqu it is about 400 mm. In the north side of the mountains, annual precipitation at Zadoi Station is about 510 mm, but at Tuotuohe it is about 280 mm. These differences in precipitation reflect the water vapour transport paths.

Fig. 4. Temporal distribution of precipitation on the south (S) and north (N) sides of the Tanggula mountains. (Average of Amdo, Nagqu and Sogxian Stations on the south side. Average of Yanshiping, Tuotuohe and Zqdoi Stations on the north side. Note the shift in vertical axes.)

In general, precipitation tends to decrease towards the interior of the continent. However, it tends to increase with altitude near the alpine region of the plateau. For example, on the south side of the Tanggula mountains annual precipitation at Nagqu Station (4507 m a.s.l.) is 406.9 mm, but at Amdo (4800 m a.s.l.) it is 441.6 mm. On the north side of the mountains, at Yanshiping Station (4720m a.s.l.), it is 100 mm more than at Tuotuohe (4533 m a.s.l.). In 1989, the measured precipitation at the terminal altitude of the Kangkyagquba Glacier, about 5250 m a.s.l., from 12 to 31 August, was 75.2 mm, but at Tuotuohe Station during the corresponding period it was only 27.9 mm. The annual accumulation in the firn area of Kangkyagquba Glacier at about 5950 m a.s.l. was 470 mm in 1987/88 and 604 mm in 1988/89, as measured in snow pits. In contrast, precipitation was only 198.5 mm (1987/88) and 326.9 mm (1988/89) at Tuotuohe Station during the corresponding accumulation periods. These results indicate that precpitation in the glacier areas is higher than in the surrounding lowlands. Using the following empirical equation between the annual precipitation (Pe; mm) and the mean annual air temperature (T ao; °C) at the ELA in China (-13°C < T ao < 2.5°C correlation coefficient is 0.95) (Reference LinyuanShi and others, 1988).

The estimated annual precipitation at the ELA in the Geladandong area is between 430 and 640 mm. If Tao averages -11.0°C, the mean annual precipitation at the ELA in the Geladandong region is approximately 520 mm. This still reflects a dry climate in the glacier area.

In addition we have to point out that local convective precipitation is frequent, especially in the firn area where showers occurred every afternoon during the field period in 1989. Observations at the terminus of Kangkyagquba Glacier from 10 August to 1 September 1989 showed that convective precipitation occurred on 12 days, with a total amount of 23.9 mm, which is 63.2% of the total number of days with precipitation, and 30.9% of the total amount of precipitation. Precipitation from synoptic-scale weather systems accounted for 69.1% of the total amount. It follows that convective precipitation cannot be ignored. Because air temperature decreases with altitude and precipitation increases with altitude, the distribution of the glaciers is closely associated with high-altitude areas. The largest glaciers all developed in the regions where the mountain peaks are more than 6000 m a.s.l. There are 50 peaks higher than 6000 m a.s.l. in the Geladandong region, and the unique ice cap and the largest valley glaciers in the Tanggula mountains are located there. The area of the glaciers in the west Tangggula mountains comprises 49.7% of the total glacierized area in the range. Another centre of present glacierization lies in the Bujarkyagri region of the east Tanggula mountains, where there are 16 mountain peaks over 6000 m a.s.l. within 20 km of each other. Large valley glaciers such as the Xuehui and Bugyai Glaciers are in this region. In the middle Tanggula mountains, where there are few peaks of more than 6000 m a.s.l., large valley glaciers are scarce although 42.9% of the total number of glaciers in the range lie in this area. The above relations between the distribution of glaciers and altitude also illustrate the influence of air temperature and precipitation on the development of glaciers. In the Geladandong area of the plateau interior, development of the present glaciers, which are found at very high altitude, depends on low air temperature and sufficient precipitation. In other areas of the range, glaciers can form at lower altitude because of higher precipitation.

Many glaciers in the Tanggula mountains are presently retreating. For example, the terminus of Kangkyagquba Glacier has retreated 520 m since 1969 (based on an aerial photograph in 1969 and a field survey in 1989), a mean retreat rate of 26 m a−1. The estimated mean mass balance of Kangkyagquba Glacier is approximately –160 mm from the 1950s to the present (Reference Yongjian and ZichuDing and Xie, 1991). Evidence for retreat of glaciers in the north end of the Geladandong area were also found during an expedition in 1976 (Reference LinyuanZhang, 1981). The mass budget for most glaciers appears to be negative.

Conclusions

Air temperature decreases northwestwards and with altitude. Moisture is carried to the Tangggula mountains along three principal paths. Precipitation decreases toward the interior of the plateau. However, precipitation tends to increase with altitude in the glaciated areas. Mean annual and summer air temperatures at the ELA are –12 to –10°C and –1.0 to 1.0°C, respectively. Annual accumulation in the firn area is about 500 mm. The glaciers are polar-continental type, reflecting a dry and cold climate. Most of the glaciers are retreating and appear to have negative mass budgets under present climatic conditions.

References

Zhongyuan, Bai. 1989.A study of relationship between climate and mountain glaciers. J. Glaciol. Geocryol., 11(4), 287297. [In Chinese with English abstract.]Google Scholar
Cheng, C.X.. 1984.An analysis of precipitation in Qinhai-Xizhang Plateau during May to August, 1979. In Symposium on Experiment of Meteorological Science in Qinhai-Xizhang Plateau. Vol. I. Beijing, Science Press, 279288.Google Scholar
Yongjian, Ding Zichu, Xie. 1991.A simple method of estimating mass balance of glacier. J. Glacial. Geocryol., 13(3), 250254. [In Chinese with English abstract.]Google Scholar
Kotlyakov, V. M. Krenke, A.N. 1982.Investigations of the hydrological conditions of alpine regions by glaciological methods. International Association of Hydrological Sciences Publication 138 (General Assembly at Exeter 1982 — Hydrological Aspects of Alpine and High-Mountain Areas), 3142.Google Scholar
Jijun, Li Benxing, Zheng 1986.The glaciers of Tibet. Beijing, Science Press.Google Scholar
Qan, Z. A. Chen, F.M. 1984.An analysis of nascent vortex during pluvial period in the west of the plateau. In Symposium on Experiment of Meteorological Science in Qinhai-Xizhang Plateau. Vol. I. Beijing, Science Press, 229242.Google Scholar
Yafeng, Shi Maohuan, Haung Binghui, Ren 1988.An introduction to the glaciers in China. Beijing, Science Press.Google Scholar
Linyuan, Zhang 1981.Glaciers at the source region of Tuotuo River in the upper reaches of the Changjiang and their evolution. J. Glaciol. Cryopedol., 3(1), 19. [In Chinese with English abstract.]Google Scholar
Figure 0

Fig. 1. Location of the research region. Numbers 1–12 also refer to Table 4.

Figure 1

Table 1. Vertical temperature gradients in °C 100 m−1 from ground to 500 mbar on the south and north sides of the Tanggula mountains (1965–80)

Figure 2

Table 2. Air temperature in °C in the Geladandong area (1960–80)

Figure 3

Table 3. Mean monthly air temperature, in °C, at mean ELA and mean terminal altitude (TAG) in various glacier systems of the Tanggula mountains (1960–80)*

Figure 4

Table 4. Air temperature, in °C, at ELA in various glacier systems of China (Shi and others, 1988)

Figure 5

Fig. 2. Temperature distribution at 4500 m a.s.l. in °C: (a) mean summer air temperature (b) mean annual air temperature. Numbers 1–8 also refer to Table 2.

Figure 6

Fig. 3. Relative frequency of wind directions at 5000 m a.s.l. on both sides of the Tanggula mountains (1960–80). (a) and (b), south side; (c) and (d), north side.

Figure 7

Fig. 4. Temporal distribution of precipitation on the south (S) and north (N) sides of the Tanggula mountains. (Average of Amdo, Nagqu and Sogxian Stations on the south side. Average of Yanshiping, Tuotuohe and Zqdoi Stations on the north side. Note the shift in vertical axes.)