Abstract
We characterized the water chemistry of nine slope wetlands and adjacent headwater streams in Colorado subalpine forests and compared sites in basins formed on crystalline bedrock with those formed in basins with a mixture of crystalline and sedimentary bedrock. The pH, Ca2+, Mg2+, NH +4 , acid neutralizing capacity, and electrical conductivity of wetland porewater and streamwater were higher in the basins with mixed geology. Bryophyte cover was higher in lower pH, crystalline basins, and vascular plant cover was higher in the mixed bedrock basins. On average, wetland porewater had lower pH and higher concentrations of dissolved organic carbon (DOC) and nitrogen and several other ions than streamwater; however, because discharge from these small wetlands is low, their direct influence on stream solute concentrations was generally undetectable. Dilution altered stream solute concentrations during peak flow in both basin types, but had little effect on wetland chemistry. In contrast to other solutes, the concentration of DOC in streams increased marginally during peak runoff and its concentration in wetland porewater was stable throughout the year. These findings further knowledge of the influence of watershed characteristics on wetland and stream chemistry and will inform future decisions regarding conservation and management in headwater basins.
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References
Alexander RR, Troendle CA, Kaufmann MR, Shepperd WD, Crouch GL, Watkins RK (1985) The Fraser Experimental Forest, Colorado: Research program and published research 1937–1985. United States Department of Agriculture, Forest Service, Rocky Mountain Forest and Range Experiment Station. Fort Collins, CO, USA. General Technical Report RM-118
Almendinger JE, Leete JH (1998) Regional and local hydrogeology of calcareous fens in the Minnesota River basin, USA. Wetlands 18:184–202
Alstatt D, Miles RL (1983) Soil survey of Grand County area, Colorado. USDA Soil Conservation Service and Forest Service and Colorado Agriculture Experiment Station. US Government Printing Office, Washington, DC
Andersson J, Nyberg L (2008) Spatial variation of wetlands and flux of dissolved organic carbon in boreal headwater catchments. Hydrological Processes 22:1965–1975
APHA (1998) Standard methods for the examination of water and wastewater, 20th edn. American Public Health Association, Washington, DC
Bedford BL (1996) The need to define hydrologic equivalence at the landscape scale for freshwater wetland mitigation. Ecological Applications 6:57–69
Bohn HL (1971) Redox potentials. Soil Science 112:39–45
Brinson MM (1993) Hydrogeomorphic classification for wetlands. Technical Report WRP-DE-4. U.S. Army Corps of Engineers Waterways Experiment Station, Vicksburg, MS
Brookshire ENJ, Valett HM, Gerber S (2009) Maintenance of terrestrial nutrient loss signatures during in-stream transport. Ecology 90:293–299
Carsey K, Kittel G, Decker K, Cooper DJ, Culver D (2003) Field guide to the wetland and riparian plant associations of Colorado. Colorado Natural Heritage Program, Colorado State University, Fort Collins
Chapman JB, Lewis B, Litus G (2003) Chemical and isotopic evaluation of water sources to the fens of South Park, Colorado. Environmental Geology 43:533–545
Chimner RA, Cooper DJ, Parton WJ (2002) Modeling carbon accumulation in Rocky Mountain fens. Wetlands 22:100–110
Cirmo CP, McDonnell JJ (1997) Linking the hydrologic and biogeochemical controls of nitrogen transport in near-stream zones of temperate-forested catchments: a review. Journal of Hydrology 199:88–120
Clow DW, Mast MA, Bullen TD, Turk JT (1997) 87Sr/86Sr as a tracer of mineral weathering reactions and calcium sources in an alpine/subalpine watershed, Loch Vale, Colorado. Water Resources Research 33:1335–1351
Cooper DJ (1990) The ecology of wetlands in Big Meadows, Rocky Mountain National Park, Colorado: the correlation of vegetation, soils and hydrology. Biological Report 90(15). US Department of the Interior, Fish and Wildlife Service, Washington, DC
Cooper DJ (1991) Additions to the peatland flora of the southern Rocky Mountains: habitat descriptions and water chemistry. Madrono 38:139–143
Cooper DJ (1996) Water and soil chemistry, floristics, and phytosociology of the extreme rich High Creek Fen in South Park, Colorado, USA. Canadian Journal of Botany 74:1801–1811
Cooper DJ (1998) Classification of Colorado’s wetlands for use in HGM functional assessment: a first approximation. In: Colorado Geological Survey, Colorado School of Mines, and Colorado State University (authors) Characterization and Functional Assessment of Reference Wetlands in Colorado. Submitted to Colorado Department of Natural Resources and US Environmental Protection Agency, Denver, CO
Cooper DJ, Andrus RE (1994) Patterns of vegetation and water chemistry in peatlands of the west-central Wind River Range, Wyoming, USA. Canadian Journal of Botany 72:1586–1597
Creed IF, Sanford SE, Beall FD, Molot LA, Dillon PJ (2003) Cryptic wetlands: integrating hidden wetlands in regression models of the export of dissolved organic carbon from forested landscapes. Hydrological Processes 17:3629–3648
Daubenmire R (1959) A canopy coverage method of vegetational analysis. Northwest Science 33:43–64
Elder K (2006) Fraser Experimental Forest East St. Louis Creek and Lower Fool Creek daily streamflow data: 1943–1985. Available via US Department of Agriculture, Forest Service, Rocky Mountain Research Station. http://www.fs.fed.us/rm/data_archive/dataaccess/FEF_ESLC_LFCRK_dailyflow.shtml. Accessed 15 Apr 2010
Eppinger RG, Theobald PK, Carlson RR (1985) Generalized geologic map of the Vasquez Peak Wilderness Study Area and the Williams Fork and St. Louis Peak Roadless Areas, Clear Creek, Grand, and Summit Counties, Colorado. Misc. Field Studies Map MF-1588-B. US Geological Survey, Reston, VA
Faulkner S, Patrick W Jr (1992) Redox processes and diagnostic wetland soil indicators in bottomland hardwood forests. Soil Science of America Journal 56:856–865
Glaser PH, Wheeler GA, Gorham E, Wright HE Jr (1981) The patterned mires of the Red Lake Peatland, northern Minnesota: vegetation, water chemistry, and landforms. Journal of Ecology 69:575–599
Gran G (1952) Determination of the equivalence point in potentiometric titrations. The Analyst 77:661–671
Hall BR, Raynal DJ, Leopold DJ (2001) Environmental influences on plant species composition in ground-water seeps in the Catskill Mountains of New York. Wetlands 21:125–134
Hill AR (1990) Groundwater flow paths in relation to nitrogen chemistry in the near-stream zone. Hydobiologia 206:39–52
Hongve D (1999) Production of dissolved organic carbon in forested catchments. Journal of Hydrology 224:91–99
Hood E, McKnight DM, Williams MW (2003) Sources and chemical character of dissolved organic carbon across an alpine/subalpine ecotone, Green Lakes Valley, Colorado Front Range. Water Resources Research 39:1188
Hough Z, Cole CA (2009) Aboveground decomposition dynamics in riparian depression and slope wetlands of central Pennsylvania. Aquatic Ecology 43:335–349
Johnson JB (1996) Phytosociology and gradient analysis of a subalpine treed fen in Rocky Mountain National Park, Colorado. Canadian Journal of Botany 74:1203–1218
Johnson JB (1997) Stand structure and vegetation dynamics of a subalpine treed fen in Rocky Mountain National Park, Colorado. Journal of Vegetation Science 8:337–342
Johnson JB (2000) The ecology of calcareous fens in Park County, Colorado. Ph.D. Dissertation, Colorado State University, Fort Collins, CO, USA
Johnson JB (2001) Documentation of reference conditions in the slope wetlands of the southern Rocky Mountains: reference database, site descriptions, and revised functional models. Technical Report, prepared for U.S. Environmental Protection Agency, Region 8 and Colorado Department of Natural Resources, Fort Collins, CO, USA
Johnson JB, Steingraeber DA (2003) The vegetation and ecological gradients of calcareous mires in the South Park valley, Colorado. Canadian Journal of Botany 81:201–219
Karlin EF, Bliss LC (1984) Variation in substrate chemistry along microtopographical and water-chemistry gradients in peatlands. Canadian Journal of Botany 62:142–153
Kaushal SS, Lewis WM Jr (2003) Patterns in the chemical fractionation of organic nitrogen in Rocky Mountain streams. Ecosystems 6:483–492
Leibowitz SG, Wigington PJ Jr, Rains MC, Downing DM (2008) Non-navigable streams and adjacent wetlands: addressing science needs following the Supreme Court’s Rapanos decision. Frontiers in Ecology and the Environment 6:364–371
Lemly J (2007) Fens of Yellowstone National Park, USA: regional and local controls over plant species distribution. M.S. Thesis, Colorado State University
Lowe WH, Likens GE (2005) Moving headwater streams to the head of the class. Bioscience 55(3):196–197
Magurran AE (1988) Ecological diversity and its measurement. Chapman and Hall, London
McCune B, Grace JB (2002) Analysis of ecological communities. MJM Software Design, Gleneden Beach, Oregon
Meyer JL, Kaplan LA, Newbold D, Strayer DL, Woltemade CJ, Zedler JB, Beilfuss R, Carpenter Q, Semlitsch R, Watzin MC, Zedler PH (2003) Where rivers are born: the scientific imperative for defending small streams and wetlands. American Rivers, Sierra Club, Washington, DC
Mielke PW, Berry KJ (2001) Permutation methods: a distance function approach. Springer, New York
Mueller SC, Stolzy LH, Fick GW (1985) Constructing and screening platinum microelectrodes for measuring soil redox potential. Soil Science 139:558–560
Retzer JL (1962) Soil survey of Fraser alpine area, Colorado Soil Survey 1956, No. 20. US Department of Agriculture, Forest Service and Soil Conservation Service and Colorado Agriculture Experiment Station, Washington, DC
Reuss JO, Stottlemyer R, Troendle CA (1997) Effect of clear cutting on nutrient fluxes in a subalpine forest at Fraser, Colorado. Hydrology and Earth System Sciences 1:333–344
SAS Institute (2002) SAS, Version 9.1. SAS Institute, Cary, NC, USA
Sjörs H (1950) On the relation between vegetation and electrolytes in north Swedish mire waters. Oikos 2(2):241–258
Soulsby C, Malcolm R, Helliwell R, Ferrier RC (1999) Hydrogeochemistry of montane springs and their influence on streams in the Cairngorm Mountains, Scotland. Hydrology and Earth System Sciences 3:409–419
Spoelstra J, Schiff SL, Semkin RG, Jeffries DS, Elgood RJ (2010) Nitrate attenuation in a small temperate wetland following forest harvest. Forest Ecology and Management 259:2333–2341
Stein ED, Mattson M, Fetscher AE, Halama KJ (2004) Influence of geologic setting on slope wetland hydrodynamics. Wetlands 24:244–260
Stottlemyer R, Troendle CA, Markowitz D (1997) Change in snowpack, soil water, and streamwater chemistry with elevation during 1990, Fraser Experimental Forest, Colorado. Journal of Hydrology 195:114–136
Taylor RB (1975) Geologic map of the Bottle Pass quadrangle, Grand County, Colorado. Geologic Quadrangle Map GQ-1224. U.S. Geological Survey, Washington, DC
Troendle CA, Reuss JO (1997) Effect of clear cutting on snow accumulation and water outflow at Fraser, Colorado. Hydrology and Earth System Sciences 1:325–332
Tweto O (1957) Geologic sketch of southern Middle Park, Colorado, Guidebook to the Geology of North and Middle Parks Basin, Colorado. Rocky Mountain Association of Geologists, Denver
Tweto O (1979) Geologic map of Colorado. U.S. Geological Survey, Washington, DC
U.S. Department of Agriculture, Natural Resource Conservation Service (2010) The PLANTS Database. Available via the National Plant Data Center. http://plants.usda.gov. Accessed 15 Feb 2010
USDA Forest Service (2001) Draft—soil and terrestrial ecological land unit survey, Arapaho and Roosevelt National Forests, Colorado. USDA Forest Service, Lakewood
Valett HM, Morrice JA, Dahm CN, Campana ME (1996) Parent lithology, surface-groundwater exchange, and nitrate retention in headwater streams. Limnology and Oceanography 41:333–345
Vitt DH, Chee WL (1990) The relationships of vegetation to surface-water chemistry and peat chemistry in fens of Alberta, Canada. Vegetatio 89:87–106
Weber WA, Wittmann RC (2007) Bryophytes of Colorado: Mosses, Liverworts, and Hornworts. Pilgrims Process Inc, Santa Fe
Windell JT, Willard BE, Cooper DJ, Foster SQ, Knud-Hansen CF, Rank LP, Kiladis GN (1986) An ecological characterization of Rocky Mountain montane and subalpine wetlands. Biological Report 86(11). US Fish and Wildlife Service, Washington, DC
Winter TC (2001) The concept of hydrologic landscapes. Journal of the American Water Resources Association 37:335–349
Wohl E, Merritt DM (2008) Reach-scale channel geometry of mountain streams. Geomorphology 93:168–185
Acknowledgments
We gratefully acknowledge K. Nelson, C. Foy, C. Geisting, and J. Shirley for field help and N. Quiet for conducting laboratory analyses. D. Cooper, R. Chimner, R. Kolka, K. Carsey, and D. Rhoades provided guidance on sampling and helped us classify study wetlands and site geology. K. Elder and M. Dixon provided stream discharge and precipitation data from the Fraser Experimental Forest. Comments from B. Johnson, D. Binkley, S. Miller and an anonymous reviewer greatly improved the text and our interpretations of the findings. L. Porth, and R. King provided advice on statistical analyses. The Department of Forest, Rangeland, and Watershed Stewardship at Colorado State University and the USDA Forest Service, Rocky Mountain Research Station provided funding for the project.
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Nelson, M.L., Rhoades, C.C. & Dwire, K.A. Influence of Bedrock Geology on Water Chemistry of Slope Wetlands and Headwater Streams in the Southern Rocky Mountains. Wetlands 31, 251–261 (2011). https://doi.org/10.1007/s13157-011-0157-8
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DOI: https://doi.org/10.1007/s13157-011-0157-8