Abstract
In a multi-strata agroforestry system in the central Amazon near Manaus, we studied the root activity distribution of different fruit trees and a legume cover crop in comparison to monocultures and a secondary forest site. Uptake of applied 32P, 33P and 15N from 0.1, 0.6 and 1.5 m depth was compared in both the dry and wet season. The results obtained with 32P were similar to those with 15N but showed a higher variability, probably due to the lower mobility of P than N in soil and thus the labeling of a smaller soil volume with 32P. During the dry season, topsoil root activity measured with 15N was around 80% for all species with the exception of the palm tree Bactris gasipaes Kunth., which had a higher uptake from 0.6 m (50%) than from 0.1 m (30%). The subsoil (1.5 m) root activity was higher, when Bactris was not regularly cut for heart of palm harvest but grown for fruit production. Additionally, relative subsoil root activity of Theobroma increased and topsoil root activity of both Bactris and Theobroma decreased when intercropped in comparison to the monoculture. During the rainy season, the topsoil tree root activity slightly increased attributable to increasing water availability near the soil surface. The lowest isotope enrichment was noted for the secondary forest trees despite their low above ground biomass. The magnitude of the isotope enrichment was related to the foliar P and less pronounced to the foliar N contents, indicating higher nutrient cycling for nutrient-rich plant species. Despite the significant subsoil root activity (1.5 m) there was little evidence that large amounts of nutrients below 1 m depth can be recycled by the investigated tree species. More important may be a rapid recycling of nutrients from 0–1 m depth.
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References
Ahenkorah Y (1975) Use of radio-active phosphorus in determining the efficiency of fertilizer utilization by cacao plantation. Plant and Soil 42: 429-439
Atkinson D and White GC (1980) Some effects of orchard soil management on the mineral nutrition of apple trees. In: Atkinson D, Jackson JE, Sharples RO and Waller WM (eds) Mineral Nutrition of Fruit Trees, pp 241-254. Butterworths, London, UK
Broeshart A and Netsinghe DA (1972) Studies on the pattern of root activity of tree crops using isotope techniques. In: IAEA Isotopes and radiation in soil plant relationships including forestry, pp 453-563. International Atomic Energy Agency, Vienna, Austria
Buresh R and Tian G (1998) Soil improvement by trees in sub-Saharan Africa. Agrofor Syst 38: 51-76
Ferreira SAN, Clement CR and Ranzani G (1980) Contribução para o conhecimento do sistema radicular da pupunheira (Bactris gasipaes H.B.K-Guiliema gasipaes (H.B.K) Bailey). Acta Amazonica 10: 245-249
Fox RL and Lipps RC (1964) A comparison of stable strontium and P32 as tracers for estimating alfalfa root activity. Plant and Soil 20: 337-350
FAO (1997) FAO/Unesco soil map of the world. Revised legend with corrections and updates. World Soil Resources, Report No. 60, ISRIC, Wageningen, The Netherlands, 119 pp
Haag D (1997) Root distribution patterns in a polycultural system with local tree crops on an acid upland soil in central Amazonia. MSc Thesis, University of Bayreuth, Bayreuth, Germany, 88 pp
Hall NS, Chandler WF, van Bavel CHM, Reid PH and Anderson JH (1953) A tracer technique to measure growth and activity of plant root systems. Techn Bull No. 101, North Carolina Agric Exp Station, Raleigh, USA, 39 pp
Huxley PA, Patel RZ, Kabaara AM and Mitchell HW (1974) Tracer studies with 32P on the distribution of functional roots of Arabica coffee in Kenya. Ann Appl Biol 77: 159-180
IAEA (1975) Root Activity Patterns of some Tree Crops. Technical Report Series No. 170, International Atomic Energy Agency, Vienna, Austria, 154 pp
Lehmann J, Peter I, Steglich C, Gebauer G, Huwe B and Zech W (1998) Below-ground interactions in dryland agroforestry. For Ecol Manage 111: 157-169
Lehmann J, da Silva Jr JP, Schroth G and da Silva LF (2000a) Nitrogen use in mixed tree crop plantations with a legume cover crop. Plant and Soil 225: 63-72
Lehmann J, da Silva Jr JP, Trujillo L and Uguen K (2000b) Legume cover crops and nutrient cycling in tropical fruit tree production. Acta Horticulturae 531: 65-72
Lehmann J, Günther D, Mota MS, Almeida MP, Zech W and Kaiser K (2001) Inorganic and organic soil phoshorous and sulfur pools in an Amazonian multistrata agroforestry system. Agrofor Syst, in press
Little TM and Hills FJ (1978) Agricultural Experimentation. Wiley and Sons, New York, USA, 350 pp
Mehlich A (1984) Mehlich 3 soil test extractant: a modification of the Mehlich 2 extractant. Commun. Soil Sci Plant Anal 15: 1409-1416
Mekonnen K, Buresh RJ and Bashir Jama (1997) Root and inorganic nitrogen distributions in sesbania fallow, natural fallow and maize fields. Plant and Soil 188: 319-327
Nascimento Filho VF and Lobão AO (1977) Detecção de 32P em amostras de origem animal e vegetal por efeito Cerenkov, cintilaçào líquida e detector GM. Boletim científico, BC-048. CENA, Piracicaba, Brazil, 25 pp
Rowe EC, Hairiah K, Giller KE, Van Noordwijk M and Cadisch G (1999) Testing the safety-net role of hedgerow tree roots by 15N placement at different soil depths. Agrofor Syst 43: 81-93
Rozanski K, Araguas-Araguas L, Plata-Bedmer A, Franke W, Tancredi AC and Tundis Vital AR (1991) Water movement in the Amazon soil traced by means of hydrogen isotopes. In: IAEA Stable Isotopes in Plant Nutrition, Soil Fertility and Environmental Studies, pp 561-563. International Atomic Energy Agency, Vienna, Austria
Sarruge JR and Haag HP (1974) Análises químicas em plantas. Escola superior de agrucultura 'Luiz de Queiroz', Brazil, 56 pp
Schroth G, da Silva L, Seixas R, Teixeira WG, Macêdo JLV and Zech W (1999) Subsoil accumulation of mineral nitrogen under polyculture and monoculture plantations, fallow and primary forest in a ferralitic Amazonian upland soil. Agric Ecosys Environm 75: 109-120
Schroth G, Lehmann J, Barros E, Rodrigues MRL and Macedo J (2001) A review of plant-soil interactions in multi-strata agroforestry systems with perennial crops. Agrofor Syst Special Publication CATIE, in review
Seyfried MS and Rao PSC (1991) Nutrient leaching loss from two contrasting cropping systems in the humid tropics. Trop Agric (Trinidad) 68: 9-18
Thomas J, Mohan Kumar B, Wahid PA, Kamalam NV and Fisher RF (1998) Root competition for phosphorus between ginger and Ailanthus triphysa in Kerala, India. Agrofor Syst 41: 293-305
Vandermeer J (1977) Observations on the root system of the pejibaye palm (Bactris gasipaes H.B.K.) in Costa Rica. Turrialba 27: 239-242
Van Wambeke A (1992) Soils of the Tropics. McGraw-Hill. New York, USA, 343 pp
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Lehmann, J., Muraoka, T. & Zech, W. Root activity patterns in an Amazonian agroforest with fruit trees determined by 32P, 33P and 15N applications. Agroforestry Systems 52, 185–197 (2001). https://doi.org/10.1023/A:1011864621062
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DOI: https://doi.org/10.1023/A:1011864621062