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Model calculations on the relative importance of internal longitudinal diffusion for aeration of roots of non-wetland plants

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Abstract

A model is presented with which the contribution of longitudinal oxygen diffusion to total oxygen requirement of a root can be estimated. Oxygen transport in and respiration of the soil are taken into account. Given the air-filled root porosity, root diameter, coefficient of oxygen transfer between root and soil, root and soil respiration rate, and the coefficient for oxygen diffusion in the soil, the maximum length a root can attain with an adequate oxygen supply to the root tip can be calculated. Results show the importance of root porosity for root aeration, also in unsaturated soils. For thick roots (radius >0.03 cm), diffusion along the internal pathway can provide 50–75% of the total oxygen requirement even, at modest values of the root porosity.

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References

  • Armstrong W 1979 Aeration in higher plants. Adv. Bot. Res. 7, 225–332.

    Google Scholar 

  • Armstrong W and Beckett P M 1985 Root aeration in unsaturated soil: multi-shelled mathematical model of oxygen diffusion and distribution with and without sectoral wet-soil blocking of the diffusion path. New Phytol. 100, 293–311.

    Google Scholar 

  • Armstrong W and Wright E J 1976 Radial oxygen loss from roots: Teh theoretical basis for the manipulation of flux data obtained by the cylindrical platinum electrode technique. Physiol. Plant 35, 21–26.

    Google Scholar 

  • Boekel P 1962 Betekenis van organische stof voor de vocht-en luchthuishouding van zandgronden. Landbkd. Tijdschr. 74, 128–135.

    Google Scholar 

  • Boekel P 1963 Soil structure and plant growth. Neth. J. Agric. Sci. 11, 120–127.

    Google Scholar 

  • Brouwer R and Wiersum L K 1977 Root aeration and crop growthIn Crop Physiology, vol. II. Ed. U S Gupta pp 157–201. New Delhi, Oxford Univ. Press and IBH Publ. Comp.

    Google Scholar 

  • Crawford R M M 1982 Physiological responses to flooding.In Physiological plant ecology. II. Water relations and carbon assimilation. Encyclop. Plant Physiology 12B. Eds. O L Lange P S Nobel, C B Osmond and H Ziegler pp 453–478. Berlin, Springer.

    Google Scholar 

  • De Willigen P and Van Noordwijk M 1984 Mathematical models on diffusion of oxygen to and within plant roots, with special emphasis on soil-root contact. I. Derivation of the models. Plant and Soil 77, 215–231.

    Google Scholar 

  • De Willigen P and Van Noordwijk M 1987 Roots, plant production and nutrient use efficiency. PhD Thesis, Wageningen Agricultural University, 281 p.

  • Grable A R 1966 Soil aeration and plant growth. Adv. Agron. 18, 58–101.

    Google Scholar 

  • Greenwood D J 1967 Studies on the transport of oxygen through the stems and roots of vegetable seedlings. New Phytol. 66, 337–347.

    Google Scholar 

  • Jensen C R, Luxmoore R J, Gundy S D and Stolzy L H 1969 Root air space measurements by a pycnometer method. Agron. J. 61, 474–475.

    Google Scholar 

  • Konings H, 1983 Formation of gas spaces (Aerenchyma) in seedling roots ofZea mays under aerated and non-aerated conditions.In Wurzelökologie und ihre Nutzanwendung. Intern. Symp. Gumpenstein 1982. Eds. W Boehm, L Kutschera and E Lichtenegger pp 761–765. Bundesanstalt Gumpenstein, Irdning, Austria.

    Google Scholar 

  • Kristensen K J and Lemon E R 1964 Soil aeration and plant root relations. III. Physical aspects of oxygen diffusion in the liquid phase of the soil. Agron. J. 56, 195–201.

    Google Scholar 

  • Luxmoore R J, Stolzy L H and Letey J 1970 Oxygen diffusion in the soil-plant system. I. A model. Agron. J. 62, 317–322.

    Google Scholar 

  • Schumacher T E and Smucker A J M 1981. Mechanical impedance effects on oxygen uptake and porosity of dry bean roots. Agron. J. 73, 51–55.

    Google Scholar 

  • Van Noordwijk M and Brouwer G, 1989 Quantification of air-filled root porosity: a comparison of two methods. Plant and Soil (In press).

  • Van Noordwijk M and De Willigen P 1984 Mathematical models on diffusion of oxygen to and within plant roots with special emphasis on soil-root contact. II. Applications. Plant and Soil 77, 233–241.

    Google Scholar 

  • Yu P T, Stolzy L H and Letey J, 1969 Survival of plants under prolonged flooded conditions. Agron. J. 61, 844–847.

    Google Scholar 

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Authors and Affiliations

  1. Institute for Soil Fertility, P.O. Box 30003, 9750 RA, Haren (Gn), The Netherlands

    P. De Willigen & M. Van Noordwijk

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  1. P. De Willigen
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  2. M. Van Noordwijk
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De Willigen, P., Van Noordwijk, M. Model calculations on the relative importance of internal longitudinal diffusion for aeration of roots of non-wetland plants. Plant Soil 113, 111–119 (1989). https://doi.org/10.1007/BF02181928

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  • DOI: https://doi.org/10.1007/BF02181928

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