Abstract
We discuss the dynamics of plant litter, the effects of litter on the chemical and physical environment, the direct and indirect effects of plant litter on plant populations and communities, and different adaptative traits that may be related to litter accumulation. The production of litter depends primarily on the site productivity, but other properties of the environment, as well as chance, may introduce important variation. The existence of time lags between the production of plant organs and their transformation into litter appears as a relevant character of litter dynamics seldom included in models. Herbivory, and other processes that destroy biomass or reduce productivity, may reduce the amount of litter produced. The destruction of litter encompasses a complex of interactions. The main processes, including physical and chemical degradation, consumption by invertebrates and decomposition, are differentially affected by the environment and by the physical and chemical characteristics of the litter itself. The relative importance of those processes varies among systems.
Litter alters the physical and chemical environment directly and indirectly. The decomposition of litter may release both nutrients and phytotoxic substances into the soil. The physical changes produced by litter also alter the activity of decomposers, resulting in an indirect effect on the chemical environment. The accumulated litter intercepts light, shading seeds and seedlings, and reduces the thermal amplitude in the soil. By reducing maximum soil temperatures, and creating a barrier to water vapor diffusion, litter reduces evaporation from the soil. However, litter may also diminish water availability when it retains a large proportion of rainfall. Litter creates a physical barrier for seedling and sprout emergence and to seeds reaching the soil.
The heterogeneity introduced into the abiotic environment by the patchy accumulation of litter may affect community structure. This effect may be both direct (when the litter of one species affects the performance of a second species) or indirect (when litter produced by one species alters the outcome of the interaction between a second and a third species).
Litter tolerance, timing of litterfall to optimize external nutrient recycling, and accumulation of litter to deter competitors (either through physical or chemical effects) have been postulated as strategies associated with litter accumulation. The existing evidence shows that only tolerance to litter accumulation admits adaptative value as the most likely explanation.
Resumen
En ésta revisión bibliográfica analizamos la dinámica de la broza, sus efectos sobre el ambiente fisico y quimíco, y los efectos directos e indirectos de la acumulación de broza sobre la estructura y dinámica de las poblaciones y comunidades vegetales. Finalmente, analizamos distintas adaptaciones de las poblaciones vegetales relacionadas con la acumulación de broza.
La cantidad de broza acumulada en un sitio depende primariamente de su productividad, pero varios otros factores ambientales, así como el azar, pueden introducir importantes variaciones. El lapso entre la formatión de un órgano y su muerte y caída, puede ser un factor de gran importancia en la dinámica de la broza. El consumo heterotrófico, así como otros factores fisicos que destruyen biomasa o reducen la productividad, también puede afectar su acumulación. La destructión de la broza constituye un proceso cuasi-sucesional. Los principales subprocesos involucrados—fragmentatión fisica, consumo por invertebrados y descomposición—son controlados por factores ambientales y por las propiedades de la broza misma.
La acumulación de broza puede afectar profundamente el ambiente físico y químico. Los cambios fisicos que induce pueden alterar la actividad de los descomponedores, mientras que su descomposición libera nutrientes y compuestos fitotóxicos en el suelo. La broza intercepta luz, sombreando semillas y plántulas, y reduciendo la amplitud térmica del suelo. Al reducir la temperature del suelo, y al crear una barrera a la difusión del vapor de agua, la broza reduce la evaporación desde el suelo. Sin embargo, puede también disminuir la disponibilidad de agua, si retiene una proporción considerable de la lluvia. Además, la broza constituye un barrera fisica que puede impedir la llegada al suelo de algunas semillas, así como dificultar la emergencia de plántulas y brotes.
Los patrones de acumulación de broza introducen heterogeneidad temporal y espacial, que puede afectar la estructura y dinámica de la comunidad. Sus efectos pueden ser directos (cuando la presencia de broza afecta el éxito de una población) o indirectos (cuando el efecto de la broza sobre una población altera el resultado de la interacción con una segunda). Adicionalmente, la broza puede afectar las comunidades de invertebrados, lo que puede a su vez repercutir en la comunidad vegetal.
Varios autores han propuesto que la tolerancia a la presencia de broza, la regulación del ciclo de nutrientes mediante distintas estrategias foliares, y la producción de broza como un medio de combatir competidores mediante sus efectos fisicos o químicos, son componentes de estrategias adaptativas de distintas poblaciones. La evidencia disponible sugiere que sólo la tolerancia a la broza acepta valor adaptativo como explicación más verosímil.
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Literature Cited
Abdul-Wahab, A. &E. Rice. 1967. Plant inhibition by Johnson grass and its possible significance in old field succession. Bull Torrey Bot. Club94: 486–497.
Al-Mufti, M. M., C. L. Sydes, S. B. Furness &S. R. Band. 1977. A quantitative analysis of shoot phenology & dominance in herbaceous vegetation. J. Ecol.65: 759–791.
Anderson, J. M. 1975. Succession, diversity and trophic relationships in some soil animals in decomposing leaf litter. J. Animal Ecol.44: 475–495.
Andren, O. &K. Paustian. 1987. Barley straw decomposition in the field: A comparison of models. Ecology68: 1190–1200.
Andrzejewska, L. &G. Gyllenberg. 1980. Small herbivore subsystem. Pages 201–267in A. I. Breymeyer & G. M. van Dyne (eds.), Grasslands, system analysis, and man. IBP 19. Cambridge University Press, New York.
Bakker, J. P. 1985. The impact of grazing on plant communities, plant populations and soil conditions in salt marshes. Vegetatio62: 391–398.
Ballaré, C. L., R. A. Sánchez, A. L. Scopel &C. M. Ghersa 1988. Morphological responses ofDatura ferox L. seedlings to the presence of neighbors. The relationship with canopy microclimate. Oecologia76: 288–293.
Barrett, L. I. 1931. Influence of forest litter on the germination and early survival of chestnut oak,Quercus montana Willd. Ecology12: 476–484.
Beatty, S. W. &O. D. V. Sholes. 1988. Leaf litter effect on plant species composition of deciduous forest treefall pits. Canad. J. Forest Res.18: 553–559.
Berendse, F., B. Berg &E. Bosatta. 1987. The effect of lignin and nitrogen on the decomposition of litter in nutrient poor ecosystems: A theoretical approach. Canad. J. Bot.65: 1116–1121.
Bergelson, J. 1990. Life after death: site preemption by the remains. ofPoa annua. Ecology71:2157–2165.
Boerner, R. E. J. 1983. Nutrient dynamics of vegetation and detritus following two intensities of fire in the New Jersey Pine Barrens. Oecologia59: 129–134.
Bokhari, V. G. 1978. Allelopathy among prairie plants and its possible ecological significance. Ann. Bot.42: 127–136.
Borchet, M. I., F. W. Davies &J. Michaelsen. 1989. Interactions of factors affecting seedling recruitment of blue oak (Quercus douglasii) in California. Ecology70: 389–404.
Bray, J. R. &E. Gorham. 1964. Litter production in forests of the world. Adv. Ecol. Res. 2: 101–187.
Bruederle, L. P. &F. W. Stearns. 1985. Ice storms damage to a southern Wisconsin mesic forest. Bull. Torrey Bot. Club112: 167–175.
Carson, W. P. &C. J. Peterson. 1990. The role of litter in an old-field community: Impact of litter quantity in different seasons on plant species richness and abundance Oecologia (Berlin)85: 8–13.
Carter, M. F. &J. B. Grace. 1986. Relative effects ofJusticia americana litter on germination, seedling and established plants ofPolygonum lapathifolium. Aquatic Bot.23: 341–349.
Chapin, F. S., III,K. van Cleve &M. C. Chapin. 1979. Soil temperature and nutrient cycling in the tussock growth form ofEriophorum vaginatum. J. Ecol.67: 169–189.
Cheplick, G. P. &J. A. Quinn. 1987. The role of seed depth, litter, and fire in the seedling establishment of amphicarpic peanut-grass (Amphicarpum purshii). Oecologia73: 459–463.
Choudhury, D. 1988. Herbivore induced changes in leaf-litter resource quality: A neglected aspect of herbivory in ecosystem nutrient dynamics. Oikos51: 389–393.
Christensen, N. L. 1985. Shrubland fire regimes and their evolutionary consequences. Pages 85–100in S. T. A. Pickett & P. S. White (eds.), The ecology of natural disturbances and patch dynamics. Academic Press, Orlando.
Christensen, O. 1975. Wood litter fall in relation to abscission, environmental factors, and the decomposition cycle in a Danish oak forest. Oikos26: 187–195.
Coelho Neto, A. L. 1987. Overland flow production in a tropical rain forest catchment: The role of litter cover. Catena14: 213–232.
Coley, P. D. 1988. Effects of plant growth rate and leaf lifetime on the amount and type of anti-herbivore defense. Oecologia74: 531–536.
—,J. P. Bryant &F. S. Chapin, III. 1985. Resource availability and plant herbivore defense. Science230: 895–899.
Collins, B. S. &J. A. Quinn. 1982. Displacement ofAndropogon scoparius on the New Jersey Piedmont by the successional shrubMyrica pennsyhanica. Amer. J. Bot69: 680–689.
Collins, S. L. &R. E. Good. 1987. The seedling regeneration niche: Habitat structure of tree seedlings in an oak-pine forest. Oikos48: 89–98.
Cotrufo, C. 1977. Nutrient content in litterfall of an Appalachian hardwood stand. J. Elisha Mitchell Sci. Soc.93: 27–33.
D’Angela, E., R. J. C. Leon &J. M. Facelli. 1986. Pioneer stages in a secondary succession of a pampean subhumid grassland. Flora178: 261–270.
Davies, R. J. 1988. Sheet mulching as an aid to broad leaved tree establishment. I. The effectiveness of various synthetic sheets compared. Forestry61: 89–96.
Day, A. D., K. L. Ludeke &J. L. Thames. 1986. Revegetation of coal mine soil with forest litter. J. Arid Environ.11: 249–252.
Day, F. P. 1983. Effects of flooding on leaf litter decomposition in microcosms. Oecologia56: 180–184.
DeJong, T. J. &P. G. L. Klinkhamer. 1985. The negative effect of litter of parent plantsof Cirsium vulgare to their offsprings. Autotoxicity or immobilization. Oecologia65: 153–166.
Deregibus, V. A., R. A. Sanchez, J. J. Casai &M. J. Trlica. 1985. Tillering responses to enrichment of red light beneath the canopy in humid natural grasslands. J. Appl. Ecol.22: 199–206.
Dix, R. L. 1960. The effect of burning on the mulch structure and species composition in grasslands in western South Dakota. Ecology41: 49–56.
Dyksterhuis, E. J. &E. M. Schmutz. 1947. Natural mulches or “litter” of grasslands, with kinds and amounts on a southern prairie. Ecology28: 163–179.
Elkins, N. Z., Y. Steinberg &W. G. Whitford. 1982. Factors affecting the applicability of the AET model for decomposition in arid environments. Ecology63: 578–580.
Ellenberg, H. 1988. Vegetation ecology of central Europe. Cambridge University Press, Cambridge.
Escudero, A. &J. M. del Arco. 1987. Ecological significance of the phenology of leaf abscission. Oikos49: 11–14.
—,M. V. Garrido &M. D. Matias. 1987. Decay curves of leaf litter from evergreen and deciduous tree species. Oecol. Plant.8: 81–87.
Evans, R. A. 1972. Germination and establishment ofSalsola in relation to seedbed environment. II. Seed distribution, germination and seedling growth ofSalsola and microenvironment monitoring of the seedbed. Agric. J.64: 219–224.
— &J. Young. 1970. Plant litter and establishment of alien annual weed species in rangeland communities. Weed Science18: 697–703.
Facelli, J. M. 1988. Response to grazing after nine years of cattle exclusion in a Flooding Pampa grassland, Argentina. Vegetatio78: 21–25.
— &W. P. Carson. 1991. Heterogeneity of plant litter accumulation in successional communities. Bull. Torrey Bot. Club118: 00–00.
—,E. D’Angela &R. J. C. León. 1987. Diversity changes during pioneer stages in a subhumid pampean grassland succession. Amer. Midl. Nat.117: 17–25.
—,C. M. Montero &R. J. C. Leon. 1988. Effect of different disturbance regimen on seminatural grasslands from the Subhumid Pampa. Flora180: 241–249.
-& S. T. A. Pickett. In press. Plant litter: Light interception and effects on an oldfield plant community. Ecology.
Feeny, P. P. 1970. Seasonal changes in oak leaf tannins and nutrients as a cause of spring feeding by winter moth caterpillars. Ecology51: 565–581.
Fenner, M. 1985. Seed ecology. Chapman & Hall, New York.
Fitter, A. H., D. Atkinson, D. J. Read &M. B. Usher. 1985. Ecological interactions in soil. Plant, microbes, and animals. Blackwell, London.
Flanagan, P. W. &K. van Cleve. 1983. Nutrient cycling in relation to composition and organic matter quality in taiga ecosystems. Canad. J. Forest Res.13: 795–817.
Fowler, N. L. 1986. Microsite requirements for germination and establishment of three grass species. Amer Midl. Nat.115: 131–145.
— 1988. What is a safe site?: Neighbor, litter, germination date, and patch effects. Ecology69: 947–961.
Frankland, J. C., J. D. Ovington &C. Macrae. 1963. Spatial and seasonal variation in soil, litter and ground vegetation in some Lake District Woodlands. J. Ecol.51: 97–112.
Furniss, P. R. &P. Ferrar. 1982. A model of savanna litter decomposition. Ecol. Model.17: 33–51.
Galuten, A. B. 1977. Bayberry and old-field succession on the New Jersey Piedmont. Henry Rutgers undergraduate Thesis. Rutgers College, New Brunswick.
Gill, R. H. 1969. Soil microarthropod abundance following oldfield litter manipulation. Ecology50: 805–816.
Gimingham, C. H. 1972. Ecology of heathlands. Halsted Press, New York.
Goldberg, D. E. &P. A. Werner. 1983. The effects of size of opening in vegetation and litter cover on seedling establishment of goldenrods (Solidago spp.). Oecologia60: 149–155.
Golley, F. B. 1965. Structure and function of an oldfield broomsedge community. Ecol. Monogr.35: 113–137.
— &J. B. Gentry. 1966. A comparison of variety and standing crop of vegetation on a one year and twelve year abandoned field. Oikos15: 185–199.
Grime, J. P. 1979. Plant strategies and vegetation processes. John Wiley & Son, New York.
Grisez, T. J. 1960. Slash helps protect seedlings from deer browsing. J. Forest.58: 385–387.
Gross, K. L. &P. A. Werner. 1982. Colonizing abilities of biennial plant species in relation to ground cover: Implications for their distributions in a successional sere. Ecology63: 921–931.
Grubb, P. J. 1977. The maintenance of species richness in plant communities: The importance of the regeneration niche. Biol. Rev.82: 107–145.
Gunnarsson, T., P. Syndin &A. Tunlid. 1988. The importance of leaf litter fragmentation for bacterial growth. Oikos52: 303–308.
Hagvar, S. 1988. Decomposition studies in an easily-constructed microcosm: Effect of microarthropods and varying soil pH. Pedobiologia31: 293–303.
Hamrick, J. L. &J. M. Lee. 1987. Effects of soil surface topography and litter cover on germination, survival and growth of musk thistle. Amer. J. Bot.74: 451–457.
Harmon, M. E., J. F. Franklin, F. J. Swanson, P. Sollins, S. V. Gregory, J. D. Lattin, N. H. Anderson, S. P. Cline, N. G. Aumen, J. R. Sedell G. W. Lienkaemper, K. Cromack, Jr. &K. W. Cummins. 1986. Ecology of coarse woody debris in temperate ecosystems. Adv. Ecol. Res.15: 133–302.
Harper, J. L. 1977. Population biology of plants. Academic Press, New York.
Harrison, P. G. &K. H. Mann 1975. Detritus formation from eel-grass (Zostera marina), the relative effect of fragmentation, leaching and decay. Limnol. Oceanogr.20: 924–934.
Haslam, S. M. 1971. Community regulation inPhragmites communis Trim. I. Monodominant stands. J. Ecol.59: 65–73.
Heady, H. F. 1956. Changes in the central California annual plant community induced by the manipulation of natural mulch. Ecology37: 798–811.
Heidjen, L. A. M. van der, V. Claessen &N. de Cock. 1983. Influence of vegetation on acoustic properties of soils. Oecologia56: 226–233.
Herman, R. K. &W. W. Chilcote. 1965. Effect of seedbed on germination and survival of Douglas fir. Res. Paper Oregon For. Res. Lab.4: 1–28.
Hermy, M. 1987. Path analysis of standing crop and environmental variables in the field layer of two Belgian riverine forests. Vegetatio70: 127–133.
Holland, E. A. &D. C. Coleman. 1987. Litter placement effects on microbial and organic matter dynamics in an agroecosystem. Ecology68: 425–433.
Hollinger, D. Y. 1986. Herbivory and the cycling of nitrogen and phosphorus in isolated California oak trees. Oecologia70: 291–297.
Hopkins, B. 1966. Vegetation of the Olokemeji forest Reserve, Nigeria. IV. The litter and soil, with special reference to their seasonal changes. J. Ecol.54: 687–703.
Horner, J. D., J. R. Gosz &R. G. Cates. 1988. The role of carbon based metabolites in decomposition in terrestrial ecosystems. Amer. Nat.132: 869–883.
Hulbert, L. C. 1969. Fire and litter effects in undisturbed bluestem prairie in Kansas. Ecology50: 874–877.
Hunt, H. W. 1978. A simulation model for decomposition in grasslands. Pages 155–183in G. Innis (ed.), Grassland simulation models. Springer, New York.
Jenny, H., S. P. Gessel &F. T. Bingham 1949. Comparative study of decomposition rates of organic matter in temperate and tropical regimes. Soil Science.68: 419–432.
Kaiser, P. 1983. The role of soil micro-organisms in savanna ecosystem. Pages 541–558in F Boulière (ed.), Tropical savannas. Elsevier, Oxford.
Keever, C. 1973. Distribution of major forest species in southeastern Pennsylvania. Ecol. Monogr.43: 303–327.
Kellman, M. 1979. Soil enrichment by Neotropical savanna trees. J. Ecol.67: 565–577.
Kenworthy, W. J., C. Currin &G. Thayer. 1987. The abundance, biomass and acetylene reduction activity of bacteria associated to decomposing rhizomes of two seagrasses,Zostera marina andThalassia testudinum. Aquatic Bot.27: 97–119.
Killingbeck, K. T. &S. A. Costigan 1988. Element resorption in a guild of understory shrub species: Niche differentiation and resorption threshold. Oikos53: 366–374.
Knapp, A. K. &T. R. Seastedt 1986. Detritus accumulation limits productivity of tallgrass prairie. BioScience36: 622–668.
Koroleff, A. 1954. Leaf litter as a killer. J. Forestry52: 178–182.
Kozlowski, T. T. &C. E. Ahlgren. 1974. Fire and ecosystems. Academic Press, New York.
Kurihara, Y. &J. Kikkawa. 1986. Trophic relations of decomposers. Pages 127–160in J. Kikkawa & D. J. Anderson (eds.), Community ecology. Patterns and processes. Blackwell, New York.
Larson, F. &W. Whitman 1942. A comparison of used and unused grassland mesas in the badlands of South Dakota. Ecology23: 438–445.
Lee, K. E. 1985. Earthworms. Their ecology and relationship with soil and land use. Academic Press, New York.
Mack, R. N. 1984. Invaders at home range. Nat. Hist.93: 40–47.
— &D. A. Pyke 1984. The demographyof Bromus tectorum: The role of microclimate, grazing and disease. J. Ecol.72: 731–749.
MacMahon, J. A. &F. H. Wagner 1985. The Mojave, Sonora and Chihuahuan deserts of North America. Pages 105–202in M. Evenari, I. Noy-Meir & D. W. Woodall (eds.), Hot deserts and shrublands. Elsevier, New York.
Madge, D. S. 1965. Leaf fall and litter disappearance in tropical forests. Pedobiologia5: 273–288.
Marks, P. L. 1983. On the origin of the field plants of the northeastern United States. Amer. Nat.122: 210–228.
McCarthy, B. C. &J. M. Facelli. 1990. Microdisturbances in oldfields and forests: Implications for woody seedling establishment. Oikos58: 27–33.
— &W. A. Wistendahl. 1988. Hickory (Carya spp.) distribution and replacement in a second-growth oak hickory forest of southeastern Ohio. Amer. Midl. Nat.119: 156–164.
McClaugherty, C. A. &B. Berg. 1987. Cellulose, lignin and nitrogen concentrations as regulating factors in late stages of forest litter decomposition. Pedobiologia30: 101–112.
—,J. Pastor, J. D. Aber &J. M. Melillo. 1985. Forest litter decomposition in relation to soil nitrogen dynamics and litter quality. Ecology66: 259–265.
McGinnies, J. 1987. Effects of hay and straw mulches on the establishment of seeded grasses and legumes on rangeland and a coal strip mine. J. Range Managern.40: 119–121.
McKinney, A. L. 1929. Effect of forest litter on soil temperature and soil freezing in autumn and winter. Ecology10: 312–321.
Meentemeyer, V. 1978. Macroclimate and lignin control of litter decomposition rates. Ecology59: 465–472.
—,E. O. Box &R. Thompson. 1982. World patterns and amounts of terrestrial plant litter production. BioScience32: 125–128.
Mellinger, M. V. &S. J. McNaughton. 1975. Structure and function of successional vascular plant communities in central New York. Ecol. Monogr.45: 161–182.
Monk, C. D. 1966. An ecological significance of evergreeness. Ecology47: 504–505.
— &F. C. Gabrielson, Jr. 1985. Effect of shade, litter and root competition on old field vegetation in South Carolina. Bull. Torrey Bot. Club112: 383–392.
Montana, C., E. Ezcurra, A. Camillo &J. P. Delhome. 1988. Decomposition of litter in grasslands—Arid and non arid environments. J. Arid Environ.14: 55–60.
Mooney, H. A. &D. J. Parson 1973. Structure and function of the California Chaparral. An example from San Dimas. Pages 83–112in F. di Castri & H. A. Mooney (eds.), Mediterranean type ecosystems. Origin and structure. Springer, New York.
Moorhead, D. L. &J. F. Reynolds. 1989. Mechanisms of surface litter mass loss in the northern Chihuahuan desert: A reinterpretation. J. Arid Environ.16: 157–163.
Moral, R. del. 1972. On the variability of chlorogenic acid concentration. Oecologia9: 289–300.
Muller, R. N., P. J. Kalisz &T. W. Kimmerer. 1987. Intraspecific variation in production of astringent phenolics over a vegetation-resource availability gradient. Oecologia72: 211–215.
Mutch, R. W. 1970. Wildland fires and ecosytems-A hypothesis. Ecology51: 1046–1051.
Noy-Meir, I. 1985. Desert ecosystem structure and function. Pages 93–104in M. Evenari, I. Noy-Meir & D. W. Woodall (eds.), Hot deserts and shrublands. Elsevier, New York.
Odum, E. P. 1960. Organic production and turnover in old field succession. Ecology41: 34–49.
— 1969. The strategy of ecosystem development. Science164: 262–270.
Olson, J. S. 1963. Energy storage and the balance of production and decomposition in ecological systems. Ecology44: 323–331.
Orndorff, K. A. &G. E. Lang. 1981. Leaf litter redistribution in a West Virginia hardwood forest. J. Ecol.69: 225–235.
Otto, C. &L. M. Nilsson. 1981. Why do beech and oak trees retain leaves until spring? Oikos27: 387–390.
Owen, D. F. 1978. The effect of a consumer,Phytomiza ilicis, on seasonal leaf fall in the holly,Ilex aquifolium. Oikos31: 268–271.
— &R. G. Wiegert. 1976. Do consumers maximize plant fitness? Oikos27: 488–492.
Pastor, J., M. A. Stillwell &D. Tilman. 1987. Little bluestem litter dynamics in Minnesota oldfields. Oecologia72: 327–330.
Penfound, W. T. 1964. Effect of denudation on the productivity of grasslands. Ecology45: 838–845.
Perino, J. V. &P. G. Risser. 1972. Some aspects of structure and function in Oklahoma oldfield succession. Bull. Torrey Bot. Club99: 233–239.
Persson, S., N. Malmer &B. Wallén. 1987. Leaf litter fall and soil acidity during half a century of secondary succession in a temperate deciduous forest. Vegetatio73: 31–45.
Peterson, C. H. 1984. Does a rigorous criterion for environmental identity preclude the existence of multiple stable points? Amer. Nat.124: 127–133.
Pickett, S. T. A., S. L. Collins &J. J. Armesto. 1987. Models, mechanisms and pathways of succession. Bot. Rev.53: 335–371.
Polunin, N. V. C. 1984. The decomposition of emergent macrophytes in fresh water. Adv. Ecol. Res.14: 115–166.
Prusienkiewicz, Z. &M. Bigos. 1978. Rhythmicity of accumulation and decomposition of forest litter in three mixed forest stands on the soils with different types of forest floor. Ekol. Polska26: 325–345.
Rhoades, D. F. &R. G. Cates. 1976. Towards a general theory of plant antiherbivores chemistry. Rec. Adv. Phytochem.10: 168–213.
Rice, E. L. 1979. Allelopathy. An update. Bot. Rev.45: 15–109.
— &R. L. Parenti. 1978. Causes of decreases in productivity in undisturbed tallgrass prairie. Amer. J. Bot.65: 1091–1097.
Richards, B. N. 1987. The microbiology of terrestrial ecosystems. Longman, London.
Riechert, S. E. &L. Bishop. 1990. Prey control by an assemblage of generalist predators: Spiders in garden test systems. Ecology71: 1441–1450.
Ring, C. B., II,R. A. Nicholson &J. L. Launchbaugh. 1985. Vegetation traits of patch-grazed Rangeland in Western-Central Kansas. J. Range Managern.38: 51–55.
Risley, L. S. &D. A. Crossley. 1988. Herbivore-caused greenfall in the southern Appalachians. Ecology69: 1118–1127.
Risser, P. G., E. C. Birney, H. D. Blocker, S. W. May, W. J. Parton &J. A. Wiens. 1979. The true prairie ecosystem. Hutchinson Ross Publ. Co., East Stroudsburg, Pennsylvania.
Rodell, C. F. 1978. Simulation of grasshopper populations in a grassland ecosystem. Pages 127–154in G. Innis (ed.), Grassland simulation models. Springer, New York.
Sala, O. E. &W. K. Lauenroth. 1983. Small rainfall events: An ecological role in semiarid regions. Oecologia53: 301–303.
Santos, P. F., N. Z. Elkins, Y. Steinberger &W. G. Whitford. 1984. A comparison of surface and buriedLarrea tridentata leaf litter decomposition in North American hot deserts. Ecology65: 278–284.
Scheu, S. 1987. The influence of earthworms (Lumbricidae) on the nitrogen dynamics in the soil litter system of a deciduous forest. Oecologia72: 197–201.
Schlatterer, E. L. &E. W. Tisdale. 1969. Effect of litter ofArtemisia, Chrysothamnus andTortula on germination and growth of three perennial grasses. Ecology50: 869–873.
Seastedt, T. R. &D. A. Crosley. 1983. Nutrients in forest litter treated with naphthalene and simulated throughfall: A field microcosm study. Soil Biol. Biochem.15: 159–165.
Shaver, G. R. 1983. Mineral nutrition and leaf longevity inLedum palustre. The role of individual nutrients and timing of leaf mortality. Oecologia56: 160–165.
Shaw, M. W. 1968. Factors affecting the regeneration of sessile oak (Quercus petrea) in North Wales. II. Acorn losses and germination under field condition. J. Ecol.56: 647–666.
Shure, D. J. &M. R. Gottschalk. 1985. Litterfall patterns in a floodplain forest. Amer. Midl. Nat114: 98–111.
— &D. L. Phillips. 1987. Litterfall patterns within different sized disturbance patches in a Southern Appalachian Mountain forest. Amer. Midl. Nat.118: 348–357.
Siegler, D. &P. W. Price. 1976. Secondary compounds in plants: Primary functions. Amer. Nat.110: 101–105.
Simpson, L. A. &F. A. Grumbs. 1986a A system of soil crop management for the wet season production of food crops on a heavy clay soil in Guyana. 1. Effect of mulching and tillage on soil properties and crop yield. Trop. Agric.63: 305–311.
——. 1986b. A system of crop and soil management for the wet season production of food crops on a heavy clay soil in Guyana. 2. Effect of mulching and tillage on germination, growth, nutrient uptake and yield. Trop. Agric.63: 311–315.
Small, J. A., M. F. Buell, H. F. Buell &T. G. Siccama. 1971. Old-field succession on the New Jersey Piedmont—The first year. William L. Hutcheson Mem. For. Bull.2: 26–30.
Sousa, W. P. &J. H. Connell. 1985. Further comments on the evidence for multiple stable points in natural communities. Amer. Nat.125: 612–615.
Spain, A. V. &R. P. Lefevre. 1987. Breakdown of four litters of contrasting quality in a tropical Australian rainforest. J. Appl. Ecol.24: 279–288.
Spence, D. H. 1982. The zonation of plants in fresh water lakes. Adv. Ecol. Res.12: 37–125.
Sprugel, D. 1984. Diversity, biomass, and nutrient cycling changes during stand development in wave regenerated balsam fir forest. Ecol. Monogr.54: 165–186.
Staaf, H. 1987. Foliage litter turnover and earthworm populations in three beech forests of contrasting soil and vegetation types. Oecologia.72: 58–64.
Stanton, N. L. 1979. Patterns of species diversity in temperate and tropical litter mites. Ecology60: 295–304.
Stiling, P. &D. Simberloff. 1989. Leaf abscission. Induced defense against pests or response to damage? Oikos55: 43–49.
Srinner, B. R., D. A. Crossley, Jr.,E. P. Odum &R. L. Tood. 1984. Nutrient budget and internal cycling of N, P, K, Ca and Mg in conventional tillage, no tillage and oldfield ecosystems on the Georgia Piedmont. Ecology65: 354–369.
Stone, E. C. &R. B. Vasey. 1968. Preservation of coastal redwood on alluvial flats. Science159: 157–161.
Stowe, L. S. 1979. Allelopathy and its influence on the distribution of plants in an Illinois old-field. J. Ecol.67: 1065–1085.
Strojan, C. L., D. C. Randall &F. B. Turner. 1987. Relationship of leaf litter decomposition rates to rainfall in the Mojave desert. Ecology68: 741–743.
Sydes, C. &J. P. Grime 1981a. Effect of tree leaf litter on herbaceous vegetation in the deciduous woodlands. I. Field investigations. J. Ecol.69: 237–248.
——. 1981b. Effects of tree leaf litter on herbaceous vegetation in the deciduous woodlands. II An experimental investigation. J. Ecol.69: 249–262.
Szczeponska, W. 1977. The effects of remains of halophytes on the growth ofPhragmites communis Trin. andTypha latifolia L. Ekol. Polska25: 437–446.
Tao, D. L., Z. B. Xu &X. Li. 1987. Effect of litter layer on natural regeneration of companion tree species in the Korean pine forest. Env. Exper. Bot.27: 53–66.
Terborgh, J. &S. Robinson. 1986. Guilds and their utility in ecology. Pages 65–90in J. Kikkawa & D. J. Anderson (eds.), Community ecology. Patterns and processes. Blackwell, New York.
Thompson, K., J. P. Grime &G. Mason. 1977. Seed germination in response to diurnal fluctuations of temperature. Nature267: 147–149.
Trèmoliere, M., R. Carbinier, A. Exiger &J. C. Turlot. 1988. Un example d’interaction non competitive entre espèces ligneuses: Le cas du lierre arborescent (Hedera helix L.) dans la forête alluviale. Oecol. Generalis9: 187–209.
Uetz, G. W. 1974. A method for measuring habitat space in studies of hardwood forest litter arthopods. Environ. Entomol.3: 313–315.
Valk, A. G. van der. 1986. The impact of litter and annual plants on recruitment from the seed bank of a lacustrine wetland. Aquatic Bot.24: 13–26.
Váazquez-Yanes, C., A. Orozco-Segovia, E. Rincón, M. E. Sánchez-Coronado, P. Huante, J. R. Toledo &V. L. Barradas. 1990. Light beneath the litter in a tropical forest: Effect on seed germination. Ecology71: 1952–1958.
Vitousek, P. M. 1984. Litterfall, nutrient cycling, and nutrient limitation in tropical forests. Ecology65: 285–298.
Wahebh, M. &A. M. Mahasheh. 1985. Some aspects of decomposition of leaf litter of the seagrassHalophila stipulacea from the gulf of Aqaba (Jordan). Aquatic Bot.21: 237–244.
Walsh, R. P. D. &P. J. Voight. 1977. Vegetation litter: An underestimated variable in hydrology and geomorphology. J. Biogeogr.4: 253–274.
Waring, R. H. &W. H. Schlesinger. 1985. Forest ecosystems. Concepts and management. Academic Press, New York.
Warren, A. L. & B. L. Zimmerman. 1987. Ecology, abundance and diversity of litter anurans in the Central Amazon, Brasil. (Abstract.) The Annual Meeting of The Association for Tropical Biology, Columbus, Ohio, USA.
Watt, A. S. 1956. Contributions to the ecology of bracken (Pteridium aquilinum). VII. Bracken and litter. 1. The origin of rings. New Phytol.55: 369–388.
— 1970. Contribution to the ecology of bracken (Pteridium aquilinum). VII. Bracken and litter. 3. The cycle of change. New Phytol69: 431–449.
— 1974. Senescence and rejuvenation in ungrazed chalk grassland (Grassland B) in Breckland: The significance of litter and moles. J. Appl. Ecol.23: 1157–1171.
Weaver, J. E. &N. W. Rowland. 1952. Effect of excessive natural mulch on the development, yield, and structure of a native grassland. Bot. Gaz.114: 1–19.
Weigert, R. G., D. C. Coleman &E. P. Odum. 1970. Energetics of litter-soil subsystems. Pages 137–148in J. Phillipson (ed.), Methods of study of soil ecology. UNESCO, Paris.
Welbank, P. J. 1963. Toxin production during decay ofAgropyron repens (couch grass) and other species. Weed Res.3: 205–214.
Werner, P. A. 1975. The effect of plant litter on germination in teasel,Dipsacus sylvestris. Amer. Midl. Nat.94: 470–476.
West, N. E. 1979. Formation, distribution, and function of plant litter in desert ecosystems. Pages 647–659in J. A. Perry & D. W. Goodall (eds.), Arid land ecosystems. Structure, function, and management. IBP vol 16. Cambridge University Press, Cambridge.
— 1985. Aboveground litter production of three temperate semidesert shrubs. Amer. Midl. Nat.113: 158–169.
Whitford, W. G., V. Meentemeyer, T. R. Seastedt, K. Comack, Jr.,D. A. Crossley, P. Santos, R. L. Todd &J. B. Waide. 1982. Exceptions to the AET model: Deserts and clearcut forest. Ecology62: 275–277.
Whittaker, R. H. 1970. Communities and ecosystems. MacMillan, New York.
— &G. M. Woodwell. 1969. Structure, production, and diversity of the oak-pine forest at Brookhaven. J. Ecol.57: 157–174.
Wiegert, R. G. &F. C. Evans. 1964. Primary production and the disappearance of dead vegetation of an old-field. Ecology45: 49–63.
Wiens, J. A. 1973. Interterritorial habitat variation in grasshopper and savanna sparrows. Ecology54: 877–884.
Williams, R. J. &D. H. Ashton. 1987. Effect of disturbance and grazing by cattle on the dynamics of heathlands and grasslands communities on the Bogong High Plains, Victoria. Austral. J. Bot.35:413–431.
Williamson, G. B. &E. M. Black. 1981. High temperature of forest fires under pines as a selective advantage over oaks. Nature293: 643–644.
Willms, W. D. 1988. Response of rough fescue (Festuca scabrella) to light, water, temperature and litter removal, under controlled conditions. Canad. J. Bot.66: 429–434.
—,S. Smoliak &A. W. Bailey. 1986. Herbage production following litter removal on Alberta native grasslands. J. Range Managern.39: 536–539.
Winn, A. A. 1985. Effects of seed size and microsite on seedling emergenceof Prunella vulgaris in four habitats. J. Ecol.73: 831–840.
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Facelli, J.M., Pickett, S.T.A. Plant litter: Its dynamics and effects on plant community structure. Bot. Rev 57, 1–32 (1991). https://doi.org/10.1007/BF02858763
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DOI: https://doi.org/10.1007/BF02858763