Abstract
Large earthen-walled lysimeters at the San Dimas Experimental Forest in southern California present a unique opportunity to assess vegetation effects on biogeochemical processes and cation release by weathering in controlled soil-vegetation systems where archived samples of soil parent material are available for comparison. The lysimeters were filled in 1937 with homogenized fine sandy loam derived on site from the weathering of diorite, and planted in 1946 with scrub oak (Quercus dumosa) and Coulter pine (Pinus coulteri). Changes in base cation contents were measured in above-ground biomass, and total and exchangeable soil pools to a depth of 1 meter. All cations in the non-exchangeable soil pool decreased relative to the initial fill material, indicating release by weathering. Sodium and K were depleted from both exchangeable and non-exchangeable pools of the soils. Plant uptake of Na was minimal, whereas K storage in vegetation exceeded the loss from the exchangeable soil pool. In both soil-vegetation systems, but especially for oak, there was an increase in exchangeable Ca and Mg. For all base cations, storage in above-ground biomass was greater for oak, whereas losses by weathering from the non-exchangeable soil pool were greater under pine. Strong evidence supports biocycling as a controlling mechanism resulting in greater Ca and Mg release by weathering under pine. In addition, decreases in non-exchangeable Ca and Mg were strongly correlated to decrease in Si under oak, whereas no correlation was observed under pine. We conclude that weathering reactions or stoichiometry differed between vegetation types.
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Alban DH, Perala DA & Schlaegel BE (1978) Biomass and nutrient distribution in aspen, pine, and spruce stands on the same soil type in Minnesota. Can. J. For. Res. 8: 290–299
Amrhein C & Suarez DL (1988) The use of surface complexation model to describe the kinetics of ligand-promoted dissolution of anorthite. Geochim. Cosmochim. Acta 52: 2785–2793
Berner RA (1990) Atmospheric carbon dioxide levels over Phanerozoic time. Science 249: 1382–1386
Bockheim JG, Leide JE & Tavella DS (1986) Distribution and cycling of macronutrients in aPinus resinosa plantation fertilized with nitrogen and potassium. Can. J. For. Res. 16: 778–785
Boyle JR & Voigt GK (1973) Biological weathering of silicate minerals: Implications for tree nutrition and soil genesis. Plant Soil 38: 191–201
Bray JR (1963) Root production and the estimation of net productivity. Can. J. Bot. 41: 65–72
Brimhall GH, Chadwick OA, Lewis CJ, Compston W, Williams IS, Danti KJ, Dietrich WE, Power ME, Hendricks D & Bratt J (1992) Deformational mass transport and invasive processes in soil evolution. Science 255: 695–702
Callaway RM, DeLucia EH & Schlesinger WH (1994) Biomass allocation of montane and desert ponderosa pine: An analog for response to climate change. Ecology 75: 1474–1481
Canadell J & Zedler PH (1994) Underground structure of woody plants in Mediterranean ecosystems of Australia, California, and Chile. In: Kalin Arroyo et al. (Eds) Ecology and biogeography of Mediterranean ecosystems of Chile, California, and Australia (pp 177–210). Springer-Verlag, New York
Chadwick OA, Kelly EF, Merrits DM & Amundson RG (1994) Carbon dioxide consumption during soil development. Biogeochem. 24: 115–127
Clayton JL (1979) Nutrient supply to soil by rock weathering. In: Impact of intensive harvesting on forest nutrient cycling (pp 75–96). Proc. Symp. USDA For. Serv. and USDOE, Syracuse, NY, August 13–16, 1979. USDA For. Serv., Northeast For. Exp. Stn, Broomall, PA
Clayton JL (1988) Some observations on the stoichiometry of feldspar hydrolysis in granitic soil. J. Environ. Qual. 17: 153–157
Clayton JL & Megahan WF (1986) Erosional and chemical denudation rates in the southwestern Idaho batholith. Earth Surface Processes and Landforms 11: 389–400
Cleaves ET, Godfrey AE & Bricker OP (1970) Geochemical balance of a small watershed and its geomorphic implications. Geol. Soc. Am. Bull. 81: 3015–3032
Colman EA & Hamilton EL (1947) The San Dimas lysimeters. U. S. For. Serv., For. Range Exp. Stn, Res. Note 47, Berkeley, CA
Crawford JM (1962) Soils of the San Dimas Experimental Forest. U.S. For. Serv., Pacific Southwest For. Rang. Exp. Stn, Misc. Paper 76, Berkeley, CA
Drever JI & Hurcomb DR (1986) Neutralization of atmospheric acidity by chemical weathering in an alpine drainage basin in the North Cascade Mountains. Geology 14: 221–224
Dunn PH, Barro SC, Wells WG, Poth MA, Wohlgemuth PM & Colver CG (1988) The San Dimas Experimental Forest: 50 years of research. U.S. For. Serv., Pacific Southwest For. Rang. Exp. Stn, Gen. Tech. Rep. PSW-104, Berkeley, CA
Edwards NT, Johnson DW, McLaughlin SB & Harris WF (1989) Carbon dynamics and productivity. In: Johnson DW & Van Hook RI (Eds) Analysis of biogeochemical cycling processes in Walker Branch watershed (pp 197–232). Springer-Verlag, New York
Ewers FW & Schmid R (1981) Longevity of needle fascicles ofPinus longaeva (Bristlecone Pine) and other north American pines. Oecologia 51: 107–115
Giovanoli R, Schnoor JL, Sigg L, Stumm W & Zobrist J (1988) Chemical weathering of crystalline rocks in the catchment area of acidic Ticino lakes, Switzerland. Clays Clay Mineral. 36: 521–529
Graham RC, Ervin JO & Wood HB (1995) Aggregate stability under oak and pine after four decades of soil development. Soil Sci. Soc. Am. J. 59: 1740–1744
Graham RC & Wood HB (1991) Morphological development and clay distribution in lysimeter soils under chaparral and pine. Soil Sci. Soc. Am. J. 55: 1638–1646
Gray JT & Schlesinger WH (1981) Nutrient cycling in Mediterranean type ecosystems. In: Miller PC (Ed) Resource use by chaparral and matorral (pp259–285). Springer-Verlag, New York
Hellmers H, Horton JS, Juhren G & O'Keefe J (1955) Root systems of some chaparral plants in southern California. Ecology 36: 667–678
Hinsinger P, Jaillard B & Dufey JE (1992) Rapid weathering of a trioctahedral mica by the roots of ryegrass. Soil Sci. Soc. Am. J. 56: 977–982
Horner JD, Gosz JR & Cates RG (1988) The role of carbon-based plant secondary metabolites in terrestrial ecosystems. Am. Nat. 132: 869–883
Jenny H (1941) Factors of soil formation. McGraw-Hill, New York
Johnson DW & Lindberg SE (1992) Atmospheric deposition and forest nutrient cycling. Springer-Verlag, New York
Johnson JE, Burger JA, Rathfon RA, Kreh RE & Feret PP (1991) Foliar nutrient comparisons of pitch pine, loblolly pine, and the pitch * loblolly hybrid. Plant Soil 132: 1–9
Johnson NM, Likens GE, Bormann FH & Pierce RS (1968) Rate of chemical weathering of silicate minerals in New Hampshire. Geochem. Cosmochem. Acta 32: 531–545
Kittredge J (1955) Litter and forest floor of the chaparral in parts of the San Dimas Experimental Forest, California. Hilgardia 23: 563–596
Knoll MA & James WC (1987) Effect of the advent and diversification of vascular land plants on mineral weathering through geologic time. Geology 15: 1099–1102
Kodama H, Schnitzer M & Jaakkimainen M (1983) Chlorite and biotite weathering by fulvic acid solutions in closed and open systems. Can J. Soil Sci. 63: 619–629
Kummerow J & Mangan R (1981) Root systems inQuercus dumosa Nutt. dominated chaparral in southern California. Acta Oecol. Plant. 2: 177–188
Laudelout H & Robert M (1994) Biogeochemistry of calcium in a broad-leaved forest ecosystem. Biogeochem. 27: 1–21
Lee KE (1985) Earthworms: Their ecology and relationships with soils and land use. Academic Press, Orlando, FL
Likens GE, Bormann FH, Johnson NM, Fisher DW & Pierce RS (1970) Effects of forest cutting and herbicide treatment on nutrient budgets in the Hubbard Brook Watershed ecosystem. Ecol. Monogr. 40: 23–47
Likens GE, Bormann FH, Pierce RS, Eaton JS & Johnson NM (1977) Biogeochemistry of a forested ecosystem. Springer-Verlag, New York
Lousier JD & Parkinson D (1978) Chemical element dynamics in decomposing leaf litter. Can. J. Bot. 56: 2795–2812
Lundström U & Öhan L-O (1990) Dissolution of feldspars in the presence of natural, organic solutes. J. Soil Sci. 41: 359–369
Marchand DE (1971) Rates and modes of denudation, White Mountains, eastern California. Am. J. Sci. 270: 109–135
Miller PC & Ng E (1977) Root:shoot biomass ratios in shrubs in southern California and central Chile. Madrono 24: 215–223
Milone K (1994) Potential effects of increasing fire frequency due to global environmental change on carbon and nitrogen emissions from the chaparral ecosystems of southern California. M. F. thesis. Duke University, Durham, NC
Mooney HA & Parsons DJ (1973) Structure and function of the California chaparral-an example from San Dimas. In: diCastru F & Mooney HA (Eds) Ecological studies, Analysis and synthesis 7: 83–111
Mortland MM, Lawton K & Uehara G (1956) Alteration of biotite to vermiculite by plant growth. Soil Sci. 82: 477–481
Mulongoy K & Bedoret A (1989) Properties of worm casts and surface soils under various plant covers in the humid tropics. Soil Biol. Biochem. 21: 197–203
National Atmospheric Deposition Program (NRSP-3)/National Trends Network (1995) NADP/NTN Coordination Office, Natural Resource Ecology Laboratory, Colorado State University, Fort Collins, CO 80523
Patric JH (1961a) The San Dimas large lysimeters. J. Soil Water Conserv. 16: 13–17
Patric JH (1961b) A forester looks at lysimeters. J. For. 59: 889–893
Pohlman AA & McColl JG (1988) Soluble organics and their role in metal dissolution. Soil Sci. Soc. Am. J. 52: 265–271
Reheis MC & Kihl R (1995) Dust deposition in southern Nevada and California, 1984–1989: Relations to climate, source area, and source lithology. J. Geophys. Res. 100: 8893–8918
Reid DA (1988) Relative contributions of vegetation types to throughfall composition. M. S. thesis. University of California, Riverside, CA
Riggan PJ, Goode S, Jacks PM & Lockwood RN (1988) Interaction of fire and community development in chaparral of southern California. Ecol. Monogr. 58: 155–176
Robert M & Berthelin J (1986) Role of biological and biochemical factors in soil mineral weathering. In: Huang PM & Schnitzer M (Eds) Interactions of soil minerals with natural organics and microbes (pp 453–495). SSSA Spec. Publ. 17. ASA, CSSA, and SSSA, Madison, WI
Santantonio D, Hermann RK & Overton WS (1977) Root biomass studies in forest ecosystems. Pedobiologia 17: 1–31
Schlesinger WH, Gray JT & Gilliam FS (1982) Atmospheric deposition processes and their importance as sources of nutrients in a chaparral ecosystem of southern California. Water Resour. Res. 18: 623–629
Schlesinger WH & Hasey MM (1980) The nutrient content of precipitation, dry fallout, and intercepted aerosols in the chaparral of southern California. Am. Midl. Nat. 103: 114–122
Schlesinger WH & Hasey MM (1981) Decomposition of chaparral shrub foliage: Losses of organic and inorganic constituents from deciduous and evergreen leaves. Ecology 62: 762–774
Schwartzman DW & Volk T (1989) Biotic enhancement of weathering and the habitability of Earth. Nature 340: 457–460
Specht RL (1988) Mediterranean-type ecosystems: A data source book. Kluwer Academic Publishers, Dordrecht, The Netherlands
Tan KH (1986) Degradation of soil minerals by organic acids. In: Huang PM & Schnitzer M (Eds) Interactions of soil minerals with natural organics and microbes (pp 1–27). SSSA Spec. Publ. 17. ASA, CSSA, and SSSA, Madison, WI
Taylor AB & Velbel MA (1991) Geochemical mass balances and weathering rates in forested watersheds of the southern Blue Ridge. II. Effects of botanical uptake terms. Geoderma 51: 29–50
Tice KR, Graham RC & Wood HB (1996) Transformations of 2:1 phyllosilicates in 41-year-old soils under oak and pine. Geoderma 70: 49–62
Ugolini FC, Dahlgren R, Shoji S & Ito T (1988) An example of andolization and podzolization as revealed by soil solution studies, southern Hokkoda, northeastern Japan. Soil Sci. 145: 111–125
Ulery AL, Graham RC, Chadwick OA & Wood HB (1995) Decade-scale changes of soil carbon, nitrogen, and exchangeable cations under chaparral and pine. Geoderma 65: 121–134
Van Breemen N, Mulder J & Driscoll CT (1983) Acidification and alkalization of soils. Plant Soil 75: 283–308
Volk T (1989) Rise of angiosperms as a factor in long-term climatic cooling. Geology 17: 107–110
Yaalon DH (1975) Conceptual models in pedogenesis: Can soil-forming factors be solved? Geoderma 14: 189–205
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Quideau, S.A., Chadwick, O.A., Graham, R.C. et al. Base cation biogeochemistry and weathering under oak and pine: a controlled long-term experiment. Biogeochemistry 35, 377–398 (1996). https://doi.org/10.1007/BF02179961
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DOI: https://doi.org/10.1007/BF02179961