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Residual phosphorus in runoff from successional forest on abandoned agricultural land: 1. Biogeochemical and hydrological processes

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Abstract

Soluble reactive phosphorus (SRP)concentrations measured in runoff fromabandoned agricultural land now in forestsuccession in the northeastern United Stateswere significantly higher than expected fromundisturbed forest land. This finding differsfrom P uptake in hardwood forest successionfollowing natural disturbance. Fieldmonitoring of a 16.6 ha old-field regrowthforest stand in the Catskills Mountains, NewYork, USA demonstrated runoff SRP trendsincluding an early summer flush that could notbe explained by simple dilution. An assay ofoutflow sediment and biomass, flowpath sedimentand biomass, forest floor leaf litter andbiomass, and Bh horizon mineral soil indicatedthat surface litter from the regrowth forestprovided the most significant contribution tothe elevated SRP in runoff. It is posited thatmicrobial mineralization of residual organic Pin surface litter coupled with the transientprocess of SRP mobilization at the soil surfaceresulting from a rising saturated layerfollowed by dissolution in surface runoff mayelevate SRP to the range observed. MeasuredSRP concentrations remain lower than reportedvalues for crop or pastureland. The resultsreported represent an important deviation fromthe prevailing view that forest land does notcontribute to eutrophication (based on enhancedP uptake in forest succession); this is aconsequence of residual P from landabandonment – a widespread practice throughoutthe northeastern US and other regions.

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References

  • Abrams MC (1988) Comparative water relations of three succession hardwood species in central Wisconsin, U.S.A. Tree Physiol. 4(3): 263-274

    Google Scholar 

  • Adamson JK &Hornung M (1990) The effect of clearfelling a Sitka spruce (Picea sitchensis) plantation on solute concentrations in drainage water. J. Hydrol. 116(1/4): 287-297

    Google Scholar 

  • Anderson SP,Dietrich WE, Torres R, Montgomery DR &Loague K (1997) Concentrationdischarge relationships in runoff from a steep, unchanneled catchment. Water Resour. Res. 33(1): 211-225

    Google Scholar 

  • Antibus RK,Sinsabaugh RL &Linkins AE (1992) Phosphatase activities and phosphorus uptake from inositol phosphate by ectomycorrhizal fungi. Can. J. Bot. 70(4): 794-801

    Google Scholar 

  • Beauchemin S,Simard RR &Cluis D (1996) Phosphorus sorption-desorption kinetics of soil under contrasting land uses. J. Environ. Qual. 25: 1317-1325

    Google Scholar 

  • Christensen S,Ronn R,Ekelund F,Andersen B,Damgaard J,Friberg-Jensen U,Jensen L,Kiil H,Larsen B &Larsen J (1996) Soil respiration profiles and protozoan enumeration agree as microbial growth indicators. Soil Biol. Biochem. 28(7): 865-868

    Google Scholar 

  • Compton JE &Cole DW (1998) Phosphorus cycling and soil P fractions in Douglas-fir and red alder stands. Forest Ecol. Managem. 110: 101–112

    Google Scholar 

  • Creed IF &Band LE (1998) Export of nitrogen from catchments within a temperate forest: Evidence for a unifying mechanism regulated by variable source area dynamics. Water Resour. Res. 34(11): 3105–3120

    Google Scholar 

  • Cross AF &Schlesinger WH (2001) Biological and geochemical controls on phosphorus fractions in semiarid soils. Biogeochem. 52: 155–172

    Google Scholar 

  • De-Steven D (1991) Experiments on mechanisms of tree establishment in old-field succession: seedling survival and growth. Ecology 72(3): 1076–1088

    Google Scholar 

  • Díaz-Raviña M,Acea MJ &Carballas T (1995) Seasonal changes in microbial biomass and nutrient flush in forest soils. Biol. Fertil. Soils 19: 220–226

    Google Scholar 

  • Edwards PJ,Parsons WV,Kochenderfer JN &Seegrist DW (1991) Effects of forest fertilization on stream water chemistry in the Appalachians. Water Resour. Bull. 27(2): 265–274

    Google Scholar 

  • Fabre A,Pinay G &Ruffinoni (1996) Seasonal changes in inorganic and organic phosphorus in the soil of a riparian forest. Biogeochem. 35: 419–432

    Google Scholar 

  • Gillespie AR &Pope PE (1991) Consequences of rhizosphere acidification on delivery and uptake kinetics of soil phosphorus. Tree Physiol. 8(2): 195–204

    Google Scholar 

  • Gressel N,McColl JG,Preston CM,Newman RH &Powers RF (1996) Linkages between phosphorus transformations and carbon decomposition in a forest soil. Biogeochem. 33(2): 97–123

    Google Scholar 

  • Haith DA,Mandel R &Wu RS (1992) Generalized Watershed Loading Functions Version 2.0 User' Manual. Dept. Agricultural & Biological Engineering. Cornell University, Ithaca, NY

    Google Scholar 

  • Haith DA &Tubbs LJ (1981) Watershed loading functions from nonpoint sources. J. Env. Engr. Div. ASCE. 107(EE1): 121–137

    Google Scholar 

  • Harding RB &Jokela EJ (1994) Long-term effects of forest fertilization on site organic matter nutrients. Soil Sci. Soc. Am. J. 58(1): 216–221

    Google Scholar 

  • Hutson JL,Wagenet RJ &Niederhofer ME (1997) Leaching Estimation and Chemistry Model (LEACHM): A Process-Based Model of Water and Solute Movement, Transformations, Plant Uptake and Chemical Reactions in the Unsaturated Zone. Research Series No. R97-1. Dept. Soil, Crop and Atmospheric Sciences. Cornell University, Ithaca, NY

    Google Scholar 

  • Illmer P &Schinner F (1992) Solubilization of inorganic phosphates by microorganisms isolated from forest soils. Soil Biol. Biochem. 4(4): 389–395

    Google Scholar 

  • Joergensen RG,Kubler H,Meyer M &Wolters V (1995) Microbial biomass phosphorus in soils of beech (Fagus sylvatica L.) forests. Biol. Fert. Soils. 19(2/3): 215–219

    Google Scholar 

  • Klausner S &Bouldin D (1983) Managing Animal Manure as a Resource-Part II: Field Management. Cooperative Extension, Ithaca, NY

    Google Scholar 

  • Lebo ME &Herrmann RB (1998) Harvest impacts on forest outflow in coastal North Carolina. J. Environ. Qual. 27: 1382–1395

    Google Scholar 

  • Likens GE &Bormann FH (1995) Biogeochemistry of a Forested Ecosystem. Springer-Verlag, New York, NY

    Google Scholar 

  • Lyons JB,Gorres JH &Amador JA (1998) Spatial and temporal variability of phosphorus retention in a riparian forest soil. J. Environ. Qual. 27: 895–903

    Google Scholar 

  • Morgan MF (1941) Chemical soil diagnosis by the universal soil testing system. Conn. Agr. Exp. Sta. Bulletin 450

  • Mou P,Fahey TJ &Hughes JW (1993) Effects of soil disturbance on vegetation recovery and nutrient accumulation following whole-tree harvest of a northern hardwood ecosystem. J. Applied Ecology. 30(4): 661–675

    Google Scholar 

  • Nair VD,Graetz DA &Reddy KR (1998) Dairy manure influences on phosphorus retention capacity of spodosols. J. Environ. Qual. 27: 522–527

    Google Scholar 

  • New York City Department of Environmental Protection (NYCDEP) (1995) Evaluation and Prioritization of the Overall Phosphorus Reduction Strategy in the Catskill and Delaware Watersheds. NYCDEP, Shokan, NY

    Google Scholar 

  • Northeast Coordinating Committee on Soil Testing (NEC-67) (1995) Recommended Soil Testing Procedures for the Northeastern United States, 2nd edn. Northeastern Regional Publication No. 493, December

  • Odum EP (1960) Organic production and turnover in old field succession. Ecol. 41: 34–49

    Google Scholar 

  • Ohrui K &Mitchell MJ (1998) Stream water chemistry in Japanese forested watersheds and its variability on a small regional scale. Water Resour. Res. 34(6): 1553–1561

    Google Scholar 

  • Omernik JM (1977) Nonpoint Source-Stream Nutrient Relationships: A Nationwide Study, EPA-600/3-77-105, September. Environmental Protection Agency, Corvallis, OR

    Google Scholar 

  • Pang PCKvKolenko H (1986) Phosphomonoesterase activity in forest soils. Soil Biol. Biochem. 18(1): 35–40

    Google Scholar 

  • Reiners WA (1992) Twenty years of ecosystem reorganization following experimental deforestation and regrowth suppression. Ecological Monographs 62(4): 503–523

    Google Scholar 

  • Rice KC &Hornberger GM (1998) Comparison of hydrochemical tracers to estimate source contributions to peak flow in a small, forested, headwater catchment. Water Resour. Res. 34(7): 1755–1766

    Google Scholar 

  • Schaffner WR &Oglesby RT (1978) Phosphorous loadings to lakes and some of their responses. Part 1. A new calculation of phosphorous loadings and its application to 13 New York lakes. Limnol. Oceanogr. 23(1): 120–134

    Google Scholar 

  • Schoenau JJ,Stewart JWB &Bettany JR (1989) Forms and cycling of phosphorus in prairie and boreal forest soils. Biogeochem. 8: 223–237

    Google Scholar 

  • Scott CA (1998a) The Hydrology of Phosphorus Transport in Watersheds of Mixed Agricultural and Forest Land Use. PhD dissertation. Cornell University, Ithaca, NY

    Google Scholar 

  • Scott CA (1998b) Comment on ‘Design for an inexpensive continuous digital output water level recorder’ by S. Reedyk et al. (Paper 97WR00678). Water Resour. Res. 34(9): 2419–2421

    Google Scholar 

  • Scott CA,Walter MF,Brooks ES,Boll J,Hes MB &Merrill MD (1998) Impacts of historical changes in land use and dairy herds on water quality in the Catskills Mountains. J. Environ. Qual. 27: 1410–1417

    Google Scholar 

  • Scott CA &Walter MF (2001) Residual phosphorus in runoff from successional forest on abandoned agricultural land: 2. hydrological and soluble reactive P budgets. Biogeochem. 55: 311–326

    Google Scholar 

  • Sharpley AN,Hedley MJ,Sibbesen E,Hillbricht-Ilkowska A,House WA &Ryszkowski L (1995) Phosphorus transfers from terrestrial to aquatic ecosystems In: Tiessen H (Ed) Phosphorus in the Global Environment: Transfers, Cycles and Management. Wiley, Chichester

    Google Scholar 

  • Sharpley AN &Smith SJ (1989) Prediction of soluble phosphorus transport in agricultural runoff. J. Environ. Qual. 18: 313–316

    Google Scholar 

  • Sharpley AN &Smith SJ (1992) Prediction of bioavailable phosphorous loss in agricultural runoff. J. Environ. Qual. 21: 32–37

    Google Scholar 

  • Standard Methods for the Examination of Water and Wastewater (1985) American Public Health Association, 16th edn. Washington, DC

  • Stanton BF &Bills NL (1996) The Return of Agricultural Lands to Forest: Changing Land Use in the Twentieth Century. E.B. 96-03. February. Dept. Agricultural, Resource, and Managerial Economics. Cornell University. Ithaca, NY

    Google Scholar 

  • Swank WT &Crossley DA Jr (Eds) (1988) Forest Hydrology and Ecology at Coweeta. Springer-Verlag, New York, NY

    Google Scholar 

  • Tiessen H,Stewart JWB &Anderson DW (1994) Determinants of resilience in soil nutrient dynamics. In: Greenland DJ &Szabolcs I (Eds) Soil Resilience and Sustainable Land Use (pp 157–170 ). CAB International.

  • Vitousek PM &Reiners WA (1975) Ecosystem succession and nutrient retention: A hypothesis. Biosci. 25(6): 376–381

    Google Scholar 

  • Vollenweider RA &Kerekes J (1980) The loading concept as a basis for controlling eutrophication: Philosophy and preliminary results of the OECD program on eutrophication. Progr. Water Technol. 12: 5–38

    Google Scholar 

  • Yanai RD (1991) Soil solution phosphorus dynamics in a whole-tree-harvested northern hardwood forest. Soil Sci. Soc. Am. J. 55: 1746–1752

    Google Scholar 

  • Yanai RD (1992) Phosphorus budget of a 70-year-old northern hardwood forest. Biogeochem. 17: 1–22

    Google Scholar 

  • Zak DR,Grigal DF,Gleeson S &Tilman D (1990) Carbon and nitrogen cycling during old-field succession: Constraints on plant and microbial biomass. Biogeochem. 11(2): 111–130

    Google Scholar 

  • Zhang Y &Mitchell MJ (1995) Phosphorus cycling in a hardwood forest in the Adirondack Mountains, New York. Can. J. For. Res. 25: 81–87

    Google Scholar 

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Authors and Affiliations

  1. India Regional Office, International Water Management Institute, c/o ICRISAT, Patancheru, A.P. 502-324, India

    Christopher A. Scott

  2. Department of Agricultural and Biological Engineering, Cornell University, Ithaca, NY, 14853, USA

    Michael F. Walter, Gregory N. Nagle, M. Todd Walter & Natalie V. Sierra

  3. Department of Biological and Agricultural Engineering, University of Idaho, Moscow, ID, 83843, USA

    Erin S. Brooks

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  1. Christopher A. Scott
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Scott, C.A., Walter, M.F., Nagle, G.N. et al. Residual phosphorus in runoff from successional forest on abandoned agricultural land: 1. Biogeochemical and hydrological processes. Biogeochemistry 55, 293–310 (2001). https://doi.org/10.1023/A:1011877214723

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