바로가기메뉴

본문 바로가기 주메뉴 바로가기

logo

  • KOREAN
  • P-ISSN2287-8327
  • E-ISSN2288-1220
  • SCOPUS, KCI

Patterns in solute chemistry of six inlet streams to Lake Hövsgöl, Mongolia

Journal of Ecology and Environment / Journal of Ecology and Environment, (P)2287-8327; (E)2288-1220
2010, v.33 no.4, pp.289-298
Tamir Puntsag (Institute of Geo-Ecology)
Jeffrey S. Owen
Myron J. Mitchell (State University of New York)
Clyde E. Goulden (Institute of Mongolian Biodiversity and Ecological Studies)
Patrick J. McHale

Abstract

A number of characteristics of the Lake Hövsgöl watershed, such as the lake’s location at the edge of the Central Asian continuous permafrost zone, provide a unique opportunity to evaluate possible anthropogenic impacts in this remote area in northern Mongolia. In this study, we compared stream solute concentrations in six sub-watersheds in the Lake Hövsgöl watershed. Water samples were collected during the summer months between 2003 and 2005. Concentrations of Cl⁻ ranged from 9.8 to 51.3 μmol/L; average nitrate concentrations were very low and ranged from undetectable to 1.1 μmol/L and average SO₄²⁻ concentration at sampling stations with minimal animal grazing ranged from 66 to 294μmol/L. Average dissolved organic carbon (DOC) concentrations ranged from 642 to 1,180 μmol C/L. We did not find statistically significant differences in DOC concentrations among the six streams, although DOC concentrations tended to be higher in the two northernmost streams, possibly related to differences in the active layer above the permafrost. Dissolved organic nitrogen (DON) concentrations were correlated with DOC concentration, and followed the same spatial pattern as those for DOC. In streams in this remote watershed, total dissolved nitrogen was made up of mostly organic N, as has been found for other regions distant from anthropogenic N sources. Overall, these results suggest that future research on the dynamics of DOC and DON in this watershed will be especially insightful in helping to understand how changes in climate and land use patterns will affect transformations, retention, and export of dissolved organic matter within these sub-watersheds in the Lake Hövsgöl region.

keywords
dissolved organic matter, grazing, Lake Hövsgöl, permafrost, watershed

Reference

1.

Aitkenhead-Peterson JA, Alexander JE, Clair TA. 2005. Dissolved organic carbon and dissolved organic nitrogen export from forested watersheds in Nova Scotia: identifying controlling factors. Global Biogeochem Cycles 19: GB4016.

2.

Ameel JJ, Axler RP, Owen CJ. 1993. Persulfate digestion for determination of total nitrogen and phosphorus in low-nutrient waters. Am Environ Lab 1: 1-11.

3.

Batkhishig O. 2006. Soils of the Lake Hövsgöl area and its watershed. In: The Geology, Biodiversity and Ecology of Lake Hövsgöl (Mongolia) (Goulden CE, Sitnikova T, Gelhaus J, Boldgiv B, eds). Backhuys Publishers, Leiden, pp 93-114.

4.

Belsky AJ, Matzke A, Uselman S. 1999. Survey of livestock influences on stream and riparian ecosystems in the western United States. J Soil Water Conserv 54: 419-431.

5.

Bormann FH, Likens GE, Fisher DW, Pierce RS. 1968. Nutrient loss accelerated by clear-cutting of a forest ecosystem. Science 159: 882-884.

6.

Brown J, Farrians OJ Jr, Heginbottom JA, Melnikov ES. 1995. Circum-Arctic Map of Permafrost and Ground Ice Conditions. USGS Circum-Pacific Map Series, Map CP-45. National Snow and Ice Data Center/World Data Center for Glaciology, Boulder, CO.

7.

Carey SK. 2003. Dissolved organic carbon fluxes in a discontinuous permafrost subarctic alpine catchment. Permafrost Periglacial Process 14: 161-171.

8.

Cronan CS, Conlan JC, Skibinski S. 1987. Forest vegetation in relation to surface water chemistry in the north branch of the Moose River, Adirondack Park, N.Y. Biogeochemistry 3: 121-128.

9.

Currie WS, Aber JD, McDowell WH, Boone RD, Magill AH. 1996. Vertical transport of dissolved organic C and N under long-term amendments in pine and hardwood forests. Biogeochemistry 35: 471-505.

10.

Dillon PJ, Kirchner WB. 1975. The effects of geology and land use on the export of phosphorus from watersheds. Water Res 9: 135-148.

11.

Goulden CE, Sitnikova T, Gelhaus J, Boldgiv B. 2006. The Geology, Biodiversity and Ecology of Lake Hövsgöl. Backhuys Publishers, Leiden.

12.

Hilbig W. 1995. The Vegetation of Mongolia. SPB Academic Publishers, Amsterdam.

13.

Holloway JM, Dahlgren RA, Hansen B, Casey WH. 1998. Contribution of bedrock nitrogen to high nitrate concentrations in stream water. Nature 395: 785-788.

14.

Kaňa J, Kopáček J. 2006. Impact of soil sorption characteristics and bedrock composition on phosphorus concentrations in two Bohemian forest lakes. Water Air Soil Pollut 173: 243-259.

15.

Lawrence GB, Lovett GM, Baevsky YH. 2000. Atmospheric deposition and watershed nitrogen export along an elevational gradient in the Catskill Mountains, New York. Biogeochemistry 50: 21-43.

16.

Li HW, Lamberti GA, Pearsons TN, Tait CK, Li JL, Buckhouse JC. 1994. Cumulative effects of riparian disturbances along high desert trout streams of the John Day Basin, Oregon. Trans Am Fish Soc 123: 627-640.

17.

Lovett GM, Weathers KC, Arthur MA, Schultz JC. 2004. Nitrogen cycling in a northern hardwood forest: Do species matter? Biogeochemistry 67: 289-308.

18.

Lowrance RR, Todd RL, Fail J Jr, Hendrickson O Jr, Leonard R, Asmussen L. 1984. Riparian forests as nutrient filters in agricultural watersheds. BioScience 34: 374-377.

19.

MacLean R, Oswood MW, Irons JG III, McDowell WH. 1999. The effect of permafrost on stream biogeochemistry: a case study of two streams in the Alaskan (U.S.A.) taiga. Biogeochemistry 47: 239-267.

20.

McHale MR, Mitchell MJ, McDonnell JJ, Cirmo CP. 2000. Nitrogen solutes in an Adirondack forested watershed: importance of dissolved organic nitrogen. Biogeochemistry 48: 165-184.

21.

Menzel DW, Corwin N. 1965. The measurement of total phosphorus in seawater based on the liberation of organically bound fractions by persulfate oxidation. Limnol Oceanography 10: 280-282.

22.

Mitchell MJ, McHale PJ, Inamdar S, Raynal DJ. 2001. Role of within-lake processes and hydrobiogeochemical changes over 16 years in a watershed in the Adirondack Mountains of New York State, U.S.A. Hydrol Process 15: 1951-1965.

23.

Myagmarjav B, Davaa G. 1999. Surface Water of Mongolia. Interpress Publishing, Ulaanbaatar. (in Mongolian)

24.

Namkhaijantsan G. 2006. Climate and climate change of the Hövsgöl region. In: The Geology, Biodiversity and Ecology of Lake Hövsgöl (Mongolia) (Goulden CE, Sitnikova T, Gelhaus J, Boldgiv B, eds). Backhuys Publishers, Leiden, pp 63-76.

25.

Nandintsetseg B, Greene JS, Goulden CE. 2007. Trends in extreme daily precipitation and temperature near Lake Hövsgöl, Mongolia. Int J Climatol 27: 341-347.

26.

Newton RM, Weintraub J, April R. 1987. The relationship between surface water chemistry and geology in the North Branch of the Moose River. Biogeochemistry 3: 21-35.

27.

Osterkamp TE, Jorgenson JC. 2006. Warming of permafrost in the Arctic National Wildlife Refuge, Alaska. Permafrost Periglacial Process 17: 65-69.

28.

Osterkamp TE, Romanovsky VE. 1999. Evidence for warming and thawing of discontinuous permafrost in Alaska. Permafrost Periglacial Process 10: 17-37.

29.

Perakis SS, Hedin LO. 2000. Nitrogen loss from unpolluted South American forests mainly via dissolved organic compounds. Nature 415: 416-419.

30.

Petrone KC, Jones JB, Hinzman LD, Boone RD. 2006. Seasonal export of carbon, nitrogen, and major solutes from Alaskan catchments with discontinuous permafrost. J Geophys Res 111: G02020.

31.

Petrone KC, Hinzman LD, Shibata H, Jones JB, Boone RD. 2007. The influence of fire and permafrost on sub-arctic stream chemistry during storms. Hydrol Process 21: 423-434.

32.

SAS. 2002. Statistical Analysis System for Windows. SAS Institute, Inc., Cary, NC.

33.

Schepers JS, Francis DD. 1982. Chemical water quality of runoff from grazing land in Nebraska: I. Influence of grazing livestock. J Environ Qual 11: 351-354.

34.

Sharkhuu A, Sharkhuu N, Etzelmuller B, Heggem ESF, Nelson FE, Shiklomanov NI, Goulden CE, Brown J. 2007. Permafrost monitoring in the Hövsgöl mountain region, Mongolia. J Geophys Res 112: F02S06.

35.

StatSoft. 2000. Statistica. StatSoft Inc., Tulsa, OK.

36.

Sueker JK, Clow DW, Ryan JN, Jarrett RD. 2001. Effect of basin physical characteristics on solute fluxes in nine alpine/subalpine basins, Colorado, USA. Hydrol Process 15: 2749-2769.

37.

Tsogtbaatar J, Goulden CE. 2000. Mongolia long term ecological research. In: The International Long Term Ecological Research Network (Gosz JR, French C, Sprott P, White M, eds). Academy Printers, Albuquerque, NM, pp 28-29.

38.

United Nations Population Division. 2006. World population prospects: the 2006 revision. http://www.un.org.esa/population/publications/wpp2006/wpp2006.htm. Accessed 5 February 2010.

Journal of Ecology and Environment