Access the full text.
Sign up today, get DeepDyve free for 14 days.
Loading next page...
/lp/springer-journals/litter-dynamics-and-soil-properties-under-different-tree-species-in-a-w1UcM9Twf8
References (46)
-
M. Swift, O. Heal, J. Anderson (1979)
Decomposition in Terrestrial Ecosystems -
D. Das, O. Chaturvedi (2003)
Litter quality effects on decomposition rates of forestry plantationsTropical Ecology, 44
-
V. Garg (1997)
Litter Production and Nutrient Concentration under High Density Plantation in Some Fuelwood Species Grown on Sodic SoilsThe Indian Forester, 123
-
J. Olson (1963)
Energy Storage and the Balance of Producers and Decomposers in Ecological SystemsEcology, 44
-
(1998)
Organic matter dynamics and nitrogen mineralization in agroforestry systems -
S. Bargali, S. Singh, R. Singh (1993)
Patterns of weight loss and nutrient release from decomposing leaf litter in an age series of eucalypt plantationsSoil Biology & Biochemistry, 25
-
H. Staaf, B. Berg (1982)
Accumulation and release of plant nutrients in decomposing Scots pine needle litter. Long-term decomposition in a Scots pine forest IIBotany, 60
-
R. Joergensen, H. Kübler, B. Meyer, V. Wolters (1995)
Microbial biomass phosphorus in soils of beech (Fagus sylvatica L.) forestsBiology and Fertility of Soils, 19
-
J. Bray, E. Gorham (1964)
Litter Production in Forests of the WorldAdvances in Ecological Research, 2
-
G. Tian, B. Kang, L. Brussaard (1992)
Biological effects of plant residues with contrasting chemical compositions under humid tropical conditions-decomposition and nutrient releaseSoil Biology & Biochemistry, 24
-
A. Page (1982)
Methods of soil analysis. Part 2. Chemical and microbiological properties. -
A. Page, R. Miller, D. Keeney (1982)
Chemical and microbiological properties -
S. Olsen (1954)
Estimation of available phosphorus in soils by extraction with sodium bicarbonate -
W. Frankenberger, H. Abdelmagid (1985)
Kinetic parameters of nitrogen mineralization rates of leguminous crops incorporated into soilPlant and Soil, 87
-
(1934)
Rapid titration method of organic carbon of soils -
A. Singh, A. Raghubanshi, J. Singh (2004)
Impact of native tree plantations on mine spoil in a dry tropical environmentForest Ecology and Management, 187
-
(2004)
Linear models III-general linear models. In: SYSTAT II statistics II -
K. Singh, P. Singh, S. Tripathi (1999)
Litterfall, litter decomposition and nutrient release patterns in four native tree species raised on coal mine spoil at Singrauli, IndiaBiology and Fertility of Soils, 29
-
B. Kang, G. Wilson (1987)
The development of alley cropping as a promising agroforestry technology. -
(1982)
Release and accumulation of plant nutrients in needle litter during decomposition. Long term -
P. Soest, J. Robertson, B. Lewis (1991)
Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition.Journal of dairy science, 74 10
-
P. Mafongoya, K. Giller, C. Palm (2004)
Decomposition and nitrogen release patterns of tree prunings and litterAgroforestry Systems, 38
-
J. Hughes, T. Fahey, B. Browne (1987)
A better seed and litter trapCanadian Journal of Forest Research, 17
-
C. Johnson, A. Ulrich (1959)
2. Analytical methods for use in plant analysis. -
F. Mtambanengwe, H. Kirchmann (1995)
Litter from a tropical savanna woodland (Miombo) : chemical composition and C and N mineralizationSoil Biology & Biochemistry, 27
-
J. Bockheim, E. Jepsen, D. Heisey (1991)
Nutrient dynamics in decomposing leaf litter of four tree species on a sandy soil in northwestern WisconsinCanadian Journal of Forest Research, 21
-
S. Isaac, M. Nair (2006)
Litter dynamics of six multipurpose trees in a homegarden in Southern Kerala, IndiaAgroforestry Systems, 67
-
A. Walkley, I. Black (1934)
AN EXAMINATION OF THE DEGTJAREFF METHOD FOR DETERMINING SOIL ORGANIC MATTER, AND A PROPOSED MODIFICATION OF THE CHROMIC ACID TITRATION METHODSoil Science, 37
-
S. Sae-Lee, P. Vityakon, B. Prachaiyo (1992)
Effects of trees on paddy bund on soil fertility and rice growth in Northeast ThailandAgroforestry Systems, 18
-
J. Sandhu, M. Sinha, R. Ambasht (1990)
Nitrogen release from decomposing litter of Leucaena leucocephala in the dry tropicsSoil Biology & Biochemistry, 22
-
(1956)
A rapid procedure for the estimation of available N in soils -
S. George, B. Kumar (1998)
LITTER DYNAMICS AND CUMULATIVE SOIL FERTILITY CHANGES IN SILVOPASTORAL SYSTEMS OF A HUMID TROPICAL REGION IN CENTRAL KERALA, INDIAInternational Tree Crops Journal, 9
-
I. Baillie, J. Anderson, J. Ingram (1990)
Tropical Soil Biology and Fertility: A Handbook of Methods.Journal of Ecology, 78
-
C. Palm (1995)
Contribution of agroforestry trees to nutrient requirements of intercropped plantsAgroforestry Systems, 30
-
D. Bevege (1986)
Book reviewSoil productivity aspects of agroforestry: P.K.R. Nair. International Council for Research in Agroforestry (ICRAF), Nairobi, 1984. 85 pp. + 17 Fig. ISBN 92-9059-021-1Forest Ecology and Management, 17
-
O. Singh, D. Sharma, J. Rawat (1993)
Production and Decomposition of Leaf Litter in Sal, Teak, Eucalyptus and Poplar Forests in Uttar PradeshThe Indian Forester, 119
-
L. Szott, C. Palm, P. Sánchez (1991)
Agroforestry in acid soils of the humid tropics.Advances in Agronomy, 45
-
S. Gupta, J. Singh (1981)
The effect of plant species, weather variables and chemical composition of plant material on decomposition in a tropical grasslandPlant and Soil, 59
-
P. Rai, R. Yadav, K. Solanki, G. Rao, R. Singh (2001)
GROWTH AND PRUNED PRODUCTION OF MULTIPURPOSE TREE SPECIES IN SILVO-PASTORAL SYSTEMS ON DEGRADED LANDS IN SEMI-ARID REGION OF UTTAR PRADESH, INDIAForests, Trees and Livelihoods, 11
-
J. Cobo, E. Barrios, D. Kass, R. Thomas (2002)
Decomposition and nutrient release by green manures in a tropical hillside agroecosystemPlant and Soil, 240
-
C. Rich (1958)
Soil Chemical AnalysisAgronomy Journal, 50
-
V. Jamaludheen, B. Kumar (1999)
Litter of multipurpose trees in Kerala, India: variations in the amount, quality, decay rates and release of nutrientsForest Ecology and Management, 115
-
G. Tian, B. Kang, L. Brussaard (1992)
Effects of chemical composition on N, Ca, and Mg release during incubation of leaves from selected agroforestry and fallow plant speciesBiogeochemistry, 16
-
H. Steppler, P. Nair (1987)
Agroforestry: A Decade of Development -
J. Beer (1988)
Litter production and nutrient cycling in coffee (Coffea arabica) or cacao (Theobroma cacao) plantations with shade treesAgroforestry Systems, 7
-
P. Nair (1993)
An introduction to agroforestry.
- Publisher
- Springer Journals
- Copyright
- Copyright © 2008 by Springer Science+Business Media B.V.
- Subject
- Life Sciences; Agriculture; Forestry
- ISSN
- 0167-4366
- eISSN
- 1572-9680
- DOI
- 10.1007/s10457-008-9106-9
- Publisher site
- See Article on Publisher Site
Abstract
Litterfall and decomposition are the two main processes accounting for soil enrichment in agroforestry. The extent of enrichment in soil properties depends on the tree species, management practices and the quantity and quality of litter. A field investigation was carried out to study litterfall production, decay rates, release of nutrients and consequent changes in soil physicochemical properties under crowns of four multipurpose tree species (MPTs) in irrigated conditions in farm fields. The species were Prosopis cineraria (L.), Dalbergia sissoo (Roxb.) ex DC, Acacia nilotica (L.) Del. and Acacia leucophloea (Roxb.) Willd. Annual accretion of litter ranged from 36 to 54 kg tree −1 year −1 and was highest under D. sissoo and lowest under A. nilotica . Total litterfall production was in the order: P. cineraria > A. leucophloea > A. nilotica > D. sissoo . P. cineraria showed the highest NPK concentration in litter. For all MPTs, a large pulse of litterfall coincided with the winter season (November to February). Litter of P. cineraria decomposed fastest while that of A. nilotica was slowest. More than 95% of the leaf litter of P. cineraria decomposed in 6 months, of D. sissoo in 7 months and A. leucophloea and A. nilotica in 9 months. Decomposition rate of litter was highly correlated with neutral detergent fibre (NDF) ( r = −0.94) and P ( r = −0.91) concentration. N, P and K release were best correlated with NDF, acid detergent fibre (ADF), P, lignin, lignin/N and C/P ratios and NDF alone explained 88% to 94% of the variability in litter decomposition and nutrient release rates. There was significant build up of soil organic carbon and available NPK in the agrisilvicultural systems but also a decrease in soil pH. Build up in soil fertility was significantly correlated with litterfall and soil improvement was greatest under P. cineraria .
Journal
Agroforestry Systems – Springer Journals
Published: May 1, 2008