The effects of the addition to soil of alginic acid and of other forms of organic matter on soil aeration

J. H. Quastel; D. M. Webley

doi:10.1017/S0021859600007516

Extract

1. A manometric technique for the assessment of soil aeration, described in a preceding paper by Webley (1947), has been used for comparing the effects of the incorporation into soil of alginic acid (as the ion) and other organic materials on soil airwater relationships. Some of the shortcomings of the technique, as well as its advantages are described.

2. The addition of sodium alginate to a soil improves its crumb stability and its water-holding power. It is shown that the addition of 0-1 g. sodium alginate to 100 g. of the air-dried standard soil used in this work has a gross effect equivalent to an increase in the water-holding power of soil of 11%. The effect of the alginate rapidly increases to a maximum with increase of the concentration of the alginate. The incorporation of the relatively insoluble calcium alginate has but little effect on the soil airwater relationship. It is suggested that alginate confers hydrophilic properties on soil by its combination as an ion with one or more constituents of the soil particle, thereby presenting new surfaces with high water-holding powers.

3. Incorporation into soil of cellulose acetate, methyl cellulose or of carboxymethyl cellulose improves its water-air relationships.

References

REFERENCES

Buehrer, T. F. & Rose, M. S. (1943). Tech. Bull. Ariz. Agric. Exp. Sta. no. 100, pp. 155–218Google Scholar

Felber, I. M. & Gardner, V. R. (1944). Tech. Bull. Mich. Agric. Exp. Sta. no. 189, pp. 3–30.Google Scholar

Webley, D. M. (1947). J. Agric. Sci. 37, 249.CrossRef Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

ROVIRA, A. D. 1953. Use of the Warburg Apparatus in Soil Metabolism Studies. Nature, Vol. 172, Issue. 4366, p. 29.

QUASTEL, J. H. 1953. ‘Krilium’ and Synthetic Soil Conditioners. Nature, Vol. 171, Issue. 4340, p. 7.

Karabinos, J.V. and Hindert, Marjorie 1954. Vol. 9, Issue. , p. 285.

CrossRef

Martin, James P. Martin, William P. Page, J.B. Raney, W.A. and de Ment, J.D. 1955. Vol. 7, Issue. , p. 1.

CrossRef

Katznelson, H. and Stevenson, I. L. 1956. OBSERVATIONS ON THE METABOLIC ACTIVITY OF THE SOIL MICROFLORA. Canadian Journal of Microbiology, Vol. 2, Issue. 6, p. 611.

Emerson, W. W. 1956. Synthetic soil conditioners. The Journal of Agricultural Science, Vol. 47, Issue. 1, p. 117.

Chase, F. E. and Gray, P. H. H. 1957. APPLICATION OF THE WARBURG RESPIROMETER IN STUDYING RESPIRATORY ACTIVITY IN SOIL. Canadian Journal of Microbiology, Vol. 3, Issue. 2, p. 335.

Hodge, Howard M. and Metcalfe, S. Nicholas 1958. FLOCCULATION OF BACTERIA BY HYDROPHILIC COLLOIDS. Journal of Bacteriology, Vol. 75, Issue. 3, p. 258.

QUASTEL, J.H. 1963. Inorganic Nutrition of Plants. p. 671.

Farahat, A. Z. and Nopp, H. 1966. Über die Bodenatmung im Schilfgürtel des Neusiedler Sees. p. 237.

Blunden, G. Challen, S. B. and Woods, D. L. 1968. Seaweed extracts as fertilisers. Journal of the Science of Food and Agriculture, Vol. 19, Issue. 6, p. 289.

QUASTEL, JUDA HIRSCH 1983. Selected Topics in the History of Biochemistry Personal Recollections. I. Vol. 35, Issue. , p. 129.

Dove, Cassandra A. Bradley, Fiona F. and Patwardhan, Siddharth V. 2016. Seaweed biopolymers as additives for unfired clay bricks. Materials and Structures, Vol. 49, Issue. 11, p. 4463.

Panova, I. G. Ilyasov, L. O. and Yaroslavov, A. A. 2021. Polycomplex Formulations for the Protection of Soils against Degradation. Polymer Science, Series C, Vol. 63, Issue. 2, p. 237.

Gupta, Shubhpriya Kulkarni, Manoj G. White, James F. Stirk, Wendy A. Papenfus, Heino B. Doležal, Karel Ördög, Vince Norrie, Jeffrey Critchley, Alan T. and Van Staden, Johannes 2021. Biostimulants for Crops from Seed Germination to Plant Development. p. 1.

Yaroslavov, A. A. Panova, I. G. Arzhakov, M. S. and Khokhlov, A. R. 2022. Interpolymer Complexes and Problem of Polymer Waste Management. Russian Journal of Applied Chemistry, Vol. 95, Issue. 4, p. 472.

Arzhakova, O. V. Arzhakov, M. S. Badamshina, E. R. Bryuzgina, E. B. Bryuzgin, E. V. Bystrova, A. V. Vaganov, G. V. Vasilevskaya, V. V. Vdovichenko, A. Yu. Gallyamov, M. O. Gumerov, R. A. Didenko, A. L. Zefirov, V. V. Karpov, S. V. Komarov, P. V. Kulichikhin, V. G. Kurochkin, S. A. Larin, S. V. Malkin, A. Ya. Milenin, S. A. Muzafarov, A. M. Molchanov, V. S. Navrotskiy, A. V. Novakov, I. A. Panarin, E. F. Panova, I. G. Potemkin, I. I. Svetlichny, V. M. Sedush, N. G. Serenko, O. A. Uspenskii, S. A. Philippova, O. E. Khokhlov, A. R. Chvalun, S. N. Sheiko, S. S. Shibaev, A. V. Elmanovich, I. V. Yudin, V. E. Yakimansky, A. V. and Yaroslavov, A. A. 2022. Polymers for the future. Russian Chemical Reviews, Vol. 91, Issue. 12, p. RCR5062.

Shin, Hyo Jeong Cho, Hyun Uk and Park, Jong Moon 2023. Alginate as a Soil Conditioner: Properties, Mechanisms, and Agricultural Applications. Biotechnology and Bioprocess Engineering, Vol. 28, Issue. 5, p. 734.

Wawszczak, Alicja Kocki, Janusz and Kołodyńska, Dorota 2024. Alginate as a Sustainable and Biodegradable Material for Medical and Environmental Applications—The Case Studies. Journal of Biomedical Materials Research Part B: Applied Biomaterials, Vol. 112, Issue. 9,

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The effects of the addition to soil of alginic acid and of other forms of organic matter on soil aeration

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This article has been cited by the following publications. This list is generated based on data provided by Crossref.

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The effects of the addition to soil of alginic acid and of other forms of organic matter on soil aeration

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