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Effect of tissue phosphorus concentration on the mineralisation of nitrogen from stylo and cowpea residues

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Abstract

Laboratory studies were conducted to investigate the effect of phosphorus concentration in residues of cowpea (t Vigna unguiculata, L. Walp) and stylo (t Stylosanthes hamata, L., cv Verano) on their rate of nitrogen mineralisation when incubated in a soil whose P status was deficient for plant growth. Residues with a range of P concentrations were obtained by applying varying rates of P to soil in which the plants were grown in the field or the glasshouse. Variations in P concentration of field- or glasshouse-grown residues were not accompanied by variations in other chemical components (C:N ratio, lignin and polyphenol concentrations). Both lignin and polyphenol concentrations were higher in the field-grown than in the glasshouse-grown residues. Lignin concentration was greater in cowpea than in stylo, but polyphenols were higher in stylo. Cowpea residues mineralised N less rapidly than stylo. N mineralisation from residues with low P concentration was consistently less than from those of higher P concentration; reduced mineralisation was observed for P concentration in the residues below 1.6 g kg−1. When inorganic P was added to the residue-soil systems, N mineralisation from the residues was increased, though no interaction between the effects of adding inorganic P and P concentration in the residues was observed.

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Authors and Affiliations

  1. Department of Agriculture, University of Queensland, St. Lucia, Queensland, Australia, 4074

    S.N. Nguluu & S.A. Waring

  2. CSIRO, 306 Carmody Road, St.Lucia, Queensland, Australia, 4067 and

    S.N. Nguluu

  3. ICRISAT, Patancheru, 502324, Andhra Pradesh, India

    S.N. Nguluu & M.E. Probert

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  1. S.N. Nguluu
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  2. M.E. Probert
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  3. R.J.K. Myers
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  4. S.A. Waring
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Nguluu, S., Probert, M., Myers, R. et al. Effect of tissue phosphorus concentration on the mineralisation of nitrogen from stylo and cowpea residues. Plant and Soil 191, 139–146 (1997). https://doi.org/10.1023/A:1004261812861

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