Application of a degree-day model for determination of mass balance of Urumqi Glacier No. 1, eastern Tianshan, China

Lihua Wu; Huilin Li; Lin Wang

doi:10.1007/s12583-011-0201-x

Journal of Earth Science ›› 2011, Vol. 22 ›› Issue (4) : 470 -481. DOI: 10.1007/s12583-011-0201-x

Article

Application of a degree-day model for determination of mass balance of Urumqi Glacier No. 1, eastern Tianshan, China

Lihua Wu ¹^,²^,^a
, Huilin Li ¹
, Lin Wang ¹

Author information +

History +

PDF

Abstract

In order to verify the feasibility and stability of a degree-day model on simulating the long time series of glacier mass balance, we apply a degree-day model to simulate the mass balance of Urumqi Glacier No. 1 for the period 1987/1988–2007/2008 based on temperature and precipitation data from a nearby climate station. The model is calibrated by simulating point measurements of mass balance, mass balance profiles, and mean specific mass balance during 1987/1988–1996/1997. The optimized parameters are obtained by using a least square method to make the model fit the measured mass balance through the model calibration. The model validation (1997/1998–2007/2008) indicates that the modeled results are in good agreement with the observations. The static mass balance sensitivity of Urumqi Glacier No. 1 is analyzed by computing the mass balance of the glacier for a temperature increase of 1 °C, with and without a 5% precipitation increase, and the values for the east branch are −0.80 and −0.87 m w.e. a⁻¹·°C⁻¹, respectively, and for the west branch, the values are −0.68 and −0.74 m w.e. a⁻¹·°C⁻¹, respectively. Moreover, the analysis of the parameter stability indicates that the parameters in the model determined from the current climate condition can be applied in the prediction of the future mass balance changes for the glacier and provide a reference for extending the model to other small glaciers in western China.

Keywords

Urumqi Glacier No. 1 / degreeday model / mass balance

Cite this article

Download citation ▾

Lihua Wu, Huilin Li, Lin Wang. Application of a degree-day model for determination of mass balance of Urumqi Glacier No. 1, eastern Tianshan, China. Journal of Earth Science, 2011, 22(4): 470-481 DOI:10.1007/s12583-011-0201-x

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Anderson B., Lawson W., Owens I., . Past and Future Mass Balance of “Ka Roimata o Hine Hukatere” Franz Josef Glacier, New Zealand. Journal of Glaciology, 2006, 52(179): 597-607.

[2]	Aðalgeirsdóttir G., Johannesson T., Bjornsson H., . Response of Hofsjökull and Southern Vatnajökull, Iceland, to Climate Change. Journal of Geophysical Research, 2006, 111 F3 F03001

[3]	Arendt A. A., Echelmeyer K. A., Harrison W. D., . Rapid Wastage of Alaska Glaciers and Their Contribution to Rising Sea Level. Science, 2002, 297(5580): 382-386.

[4]	Arnold N. S., Willis I. C., Sharp M. J., . A Distributed Surface Energy Balance Model for a Small Valley Glacier, I. Development and Testing for Haut Glacier d’Arolla, Valais, Switzerland. Journal of Glaciology, 1996, 42(140): 77-89.

[5]	Braithwaite R. J.. Calculation of Degree-Days for Glacier-Climate Research. Zeitschrift für Gletscherkunde und Glazialgeologie, 1985, 20: 1-8.

[6]	Braithwaite R. J.. Positive Degree-Day Factors for Ablation on the Greenland Ice Sheet Studied by Energy Balance Modelling. Journal of Glaciology, 1995, 41(137): 153-160.

[7]	Braithwaite R. J., Olesen O. B.. Oerlemans J.. Calculation of Glacier Ablation from Air Temperature, West Greenland. Glacier Fluctuations and Climatic Change, 1989, Dordrecht: Kluwer Academic Publishers 219 233

[8]	Braithwaite R. J., Zhang Y.. Modelling Changes in Glacier Mass Balance that May Occur as a Result of Climate Changes. Geografiska Annaler, 1999, 81A(4): 489-496.

[9]	Braithwaite R. J., Zhang Y.. Sensitivity of Mass Balance of Five Swiss Glaciers to Temperature Changes Assessed by Tuning a Degree-Day Model. Journal of Glaciology, 2000, 46(152): 7-14.

[10]	Braithwaite R. J., Zhang Y., Raper S. C. B.. Temperature Sensitivity of the Mass Balance of Mountain Glaciers and Ice Caps as a Climatological Characteristic. Zeitschrift für Gletscherkunde und Glazialgeologie, 2002, 38(1): 35-61.

[11]	Braun L. N., Weber M., Schulz M.. Consequences of Climate Change for Runoff from Alpine Regions. Annals of Glaciology, 2000, 31: 19-25.

[12]	Brun E., Martin E., Simon V., . An Energy and Mass Model of Snow Cover Suitable for Operational Avalanche Forecasting. Journal of Glaciology, 1989, 35(121): 333-342.

[13]	Casal T. G. D., Kutzbach J. E., Thompson L. G.. Present and Past Ice-Sheet Mass Balance Simulations for Greenland and the Tibetan Plateau. Climate Dynamics, 2004, 23(3–4): 407-425.

[14]	Collins, E. H., 1934. Relationship of Degree-Days above Freezing to Runoff. Trans. Am. Geophys. Union, Reports and Papers, Hydrology, 624–629

[15]	De Woul M., Hock R.. Static Mass-Balance Sensitivity of Arctic Glaciers and Ice Caps Using a Degree-Day Approach. Annals of Glaciology, 2005, 42: 217-224.

[16]	Finsterwalder S., Schunk H.. Der Suldenferner. Zeitschrift des Deutschen und Oesterreichischen Alpenvereins, 1887, 18: 72-89.

[17]	Hock R.. A Distributed Temperature-Index Ice- and Snowmelt Model Including Potential Direct Solar Radiation. Journal of Glaciology, 1999, 45(149): 101-111.

[18]	Hock R.. Temperature Index Melt Modelling in Mountain Areas. Journal of Hydrology, 2003, 282(1-4): 104-115.

[19]	Hock R.. Glacier Melt: A Review of Processes and Their Modeling. Progress in Physical Geography, 2005, 29(3): 362-391.

[20]	Hock R., Jansson P., Braun L. N.. Huber U. M., Bugmann H. K. M., Reasoner M. A.. Modelling the Response of Mountain Glacier Discharge to Climate Warming. Global Change and Mountain Regions: A State of Knowledge Overview, 2005, Dordrecht: Springer 243 252

[21]	Huintjes E., Li H., Sauter T., . Degree-Day Modelling of the Surface Mass Balance of Urumqi Glacier No. 1, Tianshan, China. The Cryosphere Discussions, 2010, 4: 207-232.

[22]	Jansson P., Hock R., Schneider T.. The Concept of Glacier Storage: A Review. Journal of Hydrology, 2003, 282(1–4): 116-129.

[23]	Jóhannesson T.. The Response of Two Icelandic Glaciers to Climatic Warming Computed with a Degree-Day Glacier Mass Balance Model Coupled to a Dynamic Glacier Model. Journal of Glaciology, 1997, 43(144): 321-327.

[24]	Jóhannesson T., Sigurdsson O., Laumann T., . Degree-Day Glacier Mass Balance Modeling with Applications to Glaciers in Iceland, Norway and Greenland. Journal of Glaciology, 1995, 41(138): 345-358.

[25]	Kuhn M., Markl G., Kaser G., . Fluctuations of Climate and Mass Balance: Different Responses of Two Adjacent Glaciers. Zeitschrift für Gletscherkunde und Glazialgeologie, 1985, 21: 409-416.

[26]	Li H. L.. Glacier Dynamic Models and their Applicability for the Alpine Glaciers in China, 2010, Beijing: Graduate University of Chinese Academy of Sciences 54 58

[27]	Li Z. Q., Edwards R., Mosley-Thompson E., . Seasonal Variability of Ionic Concentrations in Surface Snow and Elution Processes in Snow-Firn Packs at the PGPI Site on Urumqi Glacier No. 1, Eastern Tianshan, China. Annals of Glaciology, 2006, 43: 250-256.

[28]	Li Z. Q., Shen Y. P., Li H. L., . Response of the Melting Urumqi Glacier No. 1 in Eastern Tianshan to Climate Change. Advances in Climate Change Research, 2008, 4: 67-72.

[29]	Li Z. Q., Wang W. B., Zhang M. J., . Observed Changes in Streamflow at the Headwaters of the Urumqi River, Eastern Tianshan, Central Asia. Hydrological Processes, 2010, 24(2): 217-224.

[30]	Liu S. Y., Ding Y. J., Wang N. L., . Mass Balance Sensitivity to Climate Change of the Glacier No. 1 at the Headwaters of the Urumqi River, Tianshan Mountains. Journal of Glaciology Geocryology, 1998, 20(1): 9-13.

[31]	Möeller M., Schneider C.. Calibration of Glacier Volume-Area Relations from Surface Extent Fluctuations and Application to Future Glacier Change. Journal of Glaciology, 2010, 56(195): 33-40.

[32]	Oerlemans J., Anderson B., Hubbard A., . Modelling the Response of Glaciers to Climate Warming. Climate Dynamics, 1998, 14(4): 267-274.

[33]	Paterson W. S. B.. The Physics of Glaciers, 1994 Third Edition Oxford: Elsevier 26 52

[34]	Rango A., Martinec J.. Revisiting the Degree-Day Method for Snowmelt Computations. Journal of the American Water Resources Association, 1995, 31(4): 657-669.

[35]	Raper S. C. B., Braithwaite R. J.. Low Sea-Level Rise Projections from Mountain Glaciers and Ice Caps under Global Warming. Nature, 2006, 439(7074): 311-313.

[36]	Schneider C., Kilian R., Glaser M.. Energy Balance in the Ablation Zone during the Summer Season at the Gran Campo Nevado Ice Cap in the Southern Andes. Global and Planetary Change, 2007, 59(1–4): 175-188.

[37]	Schuler T. V., Hock R., Jackson M., . Distributed Mass-Balance and Climate Sensitivity Modeling of Engabreen, Norway. Annals of Glaciology, 2005, 42: 395-401.

[38]	Shi Y. F., Huang M. H., Yao T. D., . Glaciers and Related Environments in China, 2008, Beijing: Science Press 1 539

[39]	Shi Y. F., Liu C. H., Wang Z. T., . Concise Glacier Inventory of China, 2005, Shanghai: Shanghai Popular Science Press 1 194

[40]	Shi Y. F., Shen Y. P., Li D. L., . Discussion on the Present Climate Change from Warm-Dry to Warm-Wet in Northwest China. Quaternary Sciences, 2003, 23(2): 152-164.

[41]	World Meteorological Organization (WMO), 1986. Intercomparison of Models of Snowmelt Runoff. Report 23. In: Operational Hydrological in Switzerland in 1986, Geneva

[42]	Yang D. Q., Kang E. S., Blumer F.. Characteristics of Precipitation in the Source Area of the Urumqi River Basin. Journal of Glaciology Geocryology, 1992, 14(3): 258-266.

[43]	Yao T. D., Wang Y. Q., Liu S. Y., . Recent Glacial Retreat in High Asia in China and Its Impact on Water Resource in Northwest China. Science in China (Series D), 2004, 47(12): 1065-1075.

[44]	Zhang Y., Liu S. Y., Ding Y. J., . Preliminary Study of Mass Balance on the Keqicar Baqi Glacier on the South Slopes of Tianshan Mountains. Journal of Glaciology Geocryology, 2006, 28(4): 477-484.