Abstract
It has been suggested that a feedback exists between the vegetation and soil whereby fertile (vs infertile) sites support species with shorter leaf life spans and higher quality litter which promotes rapid decomposition and higher soil nutrient availability. The objectives of this study were to (1) characterize and compare the C and N dynamics of dominant upland forest ecosystems in north central Wisconsin, (2) compare the nutrient use efficiency (NUE) of these forests, and (3) examine the relationship between NUE and site characteristics. Analyzing data from 24 stands spanning a moisture / nutrient gradient, we found that resource-poor stands transferred less C and N from the vegetation to the forest floor, and that N remained in the forest floor at least four times longer than in more resource-rich stands. Analyzing data by leaf habit, we found that less N was transferred to the forest floor annually via litterfall in conifer stands, and that N remained in the forest floor of these stands nearly three times longer than in hardwood stands. NUE did not differ among forests with different resource availabilities, but was greater for conifers than for hardwoods. Vitousek's (1982) index of nutrient use efficiency (INUE1)=leaf litterfall biomass / leaf litterfall N) was most closely correlated to litterfall specific leaf area and percent hardwood leaf area index, suggesting that differences in species composition may have been responsible for the differences in NUE among our stands. NUE2, defined as ANPP / leaf litterfall N, was not closely correlated to any of the site characteristics included in this analysis.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aber JD & Melillo JM (1991) Terrestrial Ecosystems. Saunders College Publishing, Philadelphia
Atjay GL, Ketner P & Duvigneaud P (1977) Terrestrial primary production and phytomass. Scope 13: 129–181
Barnes BV & Wagner WH (1981) Michigan Trees: A Guide to Trees of Michigan and the Great Lakes Region. The Univ. of Michigan Press, Ann Arbor, MI, U.S.A.
Birk EM & Vitousek PM (1986) Nitrogen availability and nitrogen use efficiency in loblolly pine stands. Ecology 67(1): 69–79
Bockheim JG, Lee SW & Leide JE (1983) Distribution and cycling of elements in aPinus resinosa plantation ecosystem, Wisconsin. Can. J. For. Res. 13: 609–619
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
Boerner REJ (1984) Nutrient fluxes in litterfall and decomposition in four forests along a gradient of soil fertility in southern Ohio. Can. J. For. Res. 14: 794–802
Boerner REJ (1985) Foliar nutrient dynamics, growth, and nutrient use efficiency ofHammamelis virginiana in three forest microsites. Can. J. Bot. 63: 1476–1481
Campbell GS (1985) Soil physics with basic. Dev. Soil Sci. No. 14
Fassnacht KS (1996) Characterization of the structure and function of upland forest ecosystems in north central Wisconsin. PhD Dissertation. Univ. of Wisconsin-Madison
Fassnacht KS, Gower ST, MacKenzie MD, Nordheim EV & Lillesand TM (1997) Estimation of the leaf area index of north central Wisconsin forests using Landsat Thematic Mapper. Remote Sens. Environ. 61(2): 229–245
Fassnacht KS & Gower ST (1997) Interrelationships among edaphic and stand characteristics, leaf area index, and aboveground net primary productivity for upland forest ecosystems in north central Wisconsin. Can J. For. Res. 27: 1058–1067
Fassnacht KS & Gower ST (1998) Comparison of soil and stand characteristics of six upland forest habitat types in north central Wisconsin. N.J. Appl. For. 15(2): 69–76
Fisher RF (1995) Amelioration of degraded rain forest soils by plantations of native trees. Soil Sci. Soc. Am. J. 59: 544–549
Gee GW & Bauder JW (1986) Methods of Soil Analysis, Part 1: Physical and Mineralogical Methods. Am. Soc. Agron., Soil Sci. Soc. Am., Madison, WI
Gholz HL, Vogel SA, Cropper Jr. WP, McKelvey K & Ewel KC (1991) Dynamics of canopy structure and light interception inPinus elliottli stands, north Florida. Ecol. Monogr. 6: 33–51
Gosz JR (1981) Nitrogen cycling in coniferous ecosystems. Ecol. Bull. (Stockholm) 33: 405–426
Gosz JR (1984) Biological factors influencing nutrient supply in forest soils. In: Bowen GD & Nambiar EKS (Eds) Nutrition of Plantation Forests (pp 119–146). Academic Press, London
Gosz JR, Likens GE & Bormann FH (1976) Organic matter and nutrient dynamics of the forest and forest floor in the Hubbard Brook Forest. Oecologia 22: 305–320
Gower ST & Son Y (1992) Differences in soil and leaf litterfall nitrogen dynamics for five forest plantations. Soil Sci. Soc. Am. J. 56(6): 1959–1966
Gries J (1995) Biomass and net primary production for a northern hardwood stand developmental sequence in the Upper Peninsula, Michigan. MS Thesis. Univ. of Wisconsin — Madison
Hobbie SE (1992) Effects of plant species on nutrient cycling. TREE 7: 336–339
Jenny HJ (1980) The Soil Resource: Origin and Behavior. Ecol. Stud. 37. Springer-Verlag
Kotar J, Kovach J & Locey C (1988) Field Guide to Forest Habitat Types of Northern Wisconsin. Dept. For., Univ. of Wisconsin — Madison & Wisconsin Dept. Nat. Res.
Landsberg JJ & Gower ST (1997) Applications of Physiological Ecology to Forest Management. Academic Press, San Diego, CA
McClaugherty CA, Pastor J & Aber JD (1985) Forest litter decomposition in relation to soil nitrogen dynamics and litter quality. Ecology 66(1): 266–275
Melillo, JM (1981) Nitrogen cycling in deciduous forests. Ecol. Bull. (Stockholm) 33: 427–442
Miller, HG (1984) Dynamics of nutrient cycling in plantation ecosystems. In: Bowen GD & Nambiar EKS (Ed) Nutrition of Plantation Forests (pp 53–78). Academic Press, London
Miller HG, Cooper JM & Miller JD (1976) Effect of nitrogen supply on nutrients in litter fall and crown leaching in a stand of Corsican pine. J. Appl. Ecol. 13: 233–248
Nihlgård B & Lindgren L (1977) Plant biomass, primary production and bioelements of three mature beech forests in south Sweden. Oikos 23: 95–104
Page AL (1982) Methods of Soil Analysis Part 2: Chemical and Microbiological Properties (2nd edn). Am. Soc. Agron., Soil Sci. Soc. Am., Madison, WI
Parkinson JA & Allen SE (1975) A wet oxidation procedure suitable for the determination of nitrogen and mineral nutrients in biological material. Commun. Soil Sci. Plant Anal. 6(1): 1–11
Pastor JP, Aber JD, McClaugherty CA & Melillo JM (1984) Aboveground production and N and P cycling along a nitrogen mineralization gradient on Blackhawk Island, Wisconsin. Ecology 65(1): 256–268
Pastor JP & Bockheim JG (1984) Distribution and cycling of nutrients in an aspen-mixedhardwood-spodosol ecosystem in northern Wisconsin. Ecology 65(2): 339–353
Perala DA & Alban DH (1982) Biomass, nutrient distribution and litterfall inPopulus, Pinus, andPicea stand on two different soils in Minnesota. Plant Soil 64: 177–192
Prescott CE, Corbin JP & Parkinson D (1989) Biomass, productivity, and nutrient-use efficiency of aboveground vegetation in four Rocky Mountain coniferous forests. Can. J. For. Res. 19: 309–317
Reich PB, Grigal DF, Aber JD & Gower ST (1997) Nitrogen mineralization and productivity in 50 hardwood and conifer stands on diverse soils. Ecology 78(2): 335–347
SAS Institute, Inc. (1990) SAS / STAT Users Guide. Version 6 (4th edn). Volumes 1–2. SAS Institute Inc., Cary, NC
Small E (1972) Photosynthetic rates in relation to nitrogen cycling as an adaptation to nutrient deficiency in peat bog plants. Can. J. Bot. 50: 2227–2233
Snedecor GW & Cochran WG (1989) Statistical Methods (8th edn). Iowa State University Press, Ames, IA
Son Y & Gower ST (1991) Aboveground nitrogen and phosphorus use by five plantationgrown trees with different leaf longevities. Biogeochem. 14: 167–391
Trofymow JA, Barclay HJ & McCullough KM (1991) Annual rates and elemental concentrations of litter fall in thinned and fertilized Douglas-fir. Can. J. For. Res. 21: 1601–1615
Tyrrell LE & Boerner REJ (1987)Larix laricina andPicea mariana: relationships among leaf life-span, foliar nutrient patterns, nutrient conservation, and growth efficiency. Can. J. Bot. 65: 1570–1577
Vitousek PM (1982) Nutrient cycling and nutrient use efficiency. Am. Nat. 119: 553–572
Vitousek PM (1984) Litterfall, nutrient cycling and nutrient limitation in tropical forests. Ecology 65: 285–298
Vitousek PM & Howanth RW (1991) Nitrogen limitation on land and in the sea: How can it occur? Biogeochem. 13: 87–115
Wedin DA & Tilman D (1990) Species effects on nitrogen cycling: a test with perennial grasses. Occologia 84: 433–441
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Fassnacht, K.S., Gowerr, S.T. Comparison of the litterfall and forest floor organic matter and nitrogen dynamics of upland forest ecosystems in north central Wisconsin. Biogeochemistry 45, 265–284 (1999). https://doi.org/10.1007/BF00993003
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00993003