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Enhancing Soil Nitrogen Use and Biological Nitrogen Fixation in Wetland Rice

Published online by Cambridge University Press:  03 October 2008

D. K. Kundu  and
J. K. Ladha
D. K. Kundu
Affiliation:
International Rice Research Institute (IRRT), Los Baños, Laguna, Philippines
J. K. Ladha
Affiliation:
International Rice Research Institute (IRRT), Los Baños, Laguna, Philippines
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Summary

The limited fossil fuel reserve available for manufacturing fertilizer nitrogen and the adverse effects of continued use of high fertilizer nitrogen doses on the environment call for a more efficient use of indigenous soil nitrogen. This paper presents several ways of enhancing soil nitrogen use in wetland rice. These involve utilizing nitrogen present in the deeper soil layers, increasing soil nitrogen mineralization rate, decreasing the loss of mineralized nitrogen from the rooting zone, and adjusting rice variety, soil flooding, and transplanting time. To sustain nitrogen fertility and productivity of ricelands, however, the original soil nitrogen levels must be maintained through natural resources like recycled crop residues and enhanced biological N2 fixation. Various ways of stimulating biological nitrogen fixation by both indigenous and exogenous agents are discussed. Since enhancement of soil nitrogen use in rice and maintenance of the original nitrogen level in soil by stimulating biological nitrogen fixation have not been examined together in the field, elaborate field experiments should be conducted to assess the impacts of such combined practices on long-term soil nitrogen fertility and productivity.

Type
Research Article
Information
Experimental Agriculture , Volume 31 , Issue 3 , July 1995 , pp. 261 - 278
Copyright
Copyright © Cambridge University Press 1995

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References

Alazard, D. & Becker, M. (1987). Acschynomene as green manure for rice. Plant and Soil 101: 141143.CrossRefGoogle Scholar
App, A., Santiago, T., Daez, C., Manguito, C., Ventura, W., Tirol, A., Po, J., Watanabe, I., De Datta, S. K. & Roger, P. A. (1984) Estimation of the nitrogen balance for irrigated rice and the contribution of phototrophic nitrogen fixation. Field Crops Research 9:1727.CrossRefGoogle Scholar
Baldani, J. I., Baldani, V. L. D., Seldin, L. & Dobereiner, J. (1986). Characterization of Herbaspirillum seropedicae gen. nov., sp. nov., a root-associated nitrogen-fixing bacterium. International Journal of Systematic Bacteriology 36:8693.CrossRefGoogle Scholar
Baldani, V. L. D., James, E., Baldani, J. I. & Dobereiner, J. (1992). Localization of the N2-fixing bacteria Herbaspirillum seropedicae within root cells of rice. Annales Academia Brasileira De Ciencias 64:431.Google Scholar
Barthakur, H. P., Aziz, T. & Watanabe, I. (1983). Effect of rice straw application on the activity of algae in rice fields. Journal of the Indian Society of Soil Science 31:146147.Google Scholar
Becker, M., Ladha, J. K. & Ottow, J. C. G. (1990) Growth and N2-fixation of two stem-nodulating legumes and their effect as green manure in lowland rice. Soil Biology and Biochemistry 22:11091119.CrossRefGoogle Scholar
Bennett, J. & Ladha, J. K. (1992). Introduction: Feasibility of nodulation and nitrogen fixation in rice. In Nodulation and Nitrogen Fixation in Rice, 1–14 (Eds Khush, G. S. and Bennett, J.). Manila, Philippines: International Rice Research Institute.Google Scholar
Boddey, R. M., de Oliveria, O. C., Urquiaga, S., Reis, V. M., de Olivares, F. L., Baldani, V. L. D. & Dobereiner, J. (1994). Biological nitrogen fixation associated with sugarcane and rice: contributions and prospects for improvement. In Transactions of the 15th World Congress of Soil Science, Volume 4a, 273292. Acapulco, Mexico.Google Scholar
Bohlool, B. B., Ladha, J. K., Garrity, D. P. & George, T. (1992). Biological nitrogen fixation for sustainable agriculture: A perspective. Plant and Soil 141:111.CrossRefGoogle Scholar
Bouldin, D. R. (1986). The chemistry and biology of flooded soils in relation to the nitrogen economy of rice fields. Fertilizer Research 9:114.CrossRefGoogle Scholar
Broadbent, F. E. (1978). Nitrogen transformation in flooded soils. In Soils and Rice, 543559. Manila, Philippines: International Rice Research Institute.Google Scholar
Broadbent, F. E. (1979). Mineralization of organic nitrogen in paddy soils. In Nitrogen and Rice, 105108. Manila, Philippines: International Rice Research Institute.Google Scholar
Buresh, R. J., Woodhead, T., Shepherd, K. D., Flordelis, E. & Cabangon, R. C. (1989). Nitrate accumulation and loss in a mungbean/lowland rice cropping system. Soil Science Society of America Journal 53:477482.CrossRefGoogle Scholar
Buresh, R. J., Chua, T. T., Castillo, E. G., Liboon, S. P. & Garrity, D. P. (1993) Fallow and Sesbania effects on soil nitrogen dynamics in lowland rice-based cropping systems. Agronomy journal 85:316321.CrossRefGoogle Scholar
Cabrera, M. L. (1993). Modeling the flush of nitrogen mineralization caused by drying and rewetting soils. Soil Science Society of America journal 57:6366.CrossRefGoogle Scholar
Cassman, K. G. & Pingali, P. L. (1994). Extrapolating trends from longterm experiments to farmers fields: the case of irrigated rice systems in Asia. In Agricultural Stainability in Economic, Environmental, and Statistical Terms (Eds Barnett, V., Payne, R. and Steiner, R.). London: John Wiley & Sons. (In press.)Google Scholar
Cholitkul, W., Tangcham, B., Sangtong, P. & Watanabe, I. (1980). Effect of phosphorus on N2-fixation measured by field acetylene reduction technique in Thailand longterm fertility plots. Soil Science and Plant Nutrition 26:291299.CrossRefGoogle Scholar
Conway, G. R. & Pretty, J. N. (1988). Fertilizer risks in the developing countries. Nature 334:207208.CrossRefGoogle ScholarPubMed
Craswell, E. T., Saffigna, P. G. & Waring, S. A. (1970). The mineralization of organic nitrogen in dry soil aggregates of different sizes. Plant and Soil 33:382392.CrossRefGoogle Scholar
De Datta, S. K. & Buresh, R. J. (1989). Integrated nitrogen management in irrigated rice. Advances in Soil Science 10:143169.CrossRefGoogle Scholar
De Datta, S. K. & Kundu, D. K. (1991). Fertility management of acid rice growing soils in tropical Asia: a review. In Rice Production on Acid Soils of the Tropics, 147160 (Eds Deturck, P. and Ponnamperuma, F. N.). Kandy, Sri Lanka: Institute of Fundamental Studies.Google Scholar
Dei, Y & Maeda, K. (1973). On soil structure of plowed layer of paddy field. Japan Agricultural Research Quarterly 7:8692.Google Scholar
Dei, Y. & Yamasaki, S. (1979). Effect of water and crop management on the nitrogen-supplying capacity of paddy soils. In Nitrogen and Rice, 451463. Manila, Philippines: International Rice Research Institute.Google Scholar
Do van, Cat, Watanabe, I., Zimmerman, W. J., Lumpkin, T. A. & de Waha, B. T. (1989). Sexual hybridization among Azolla species. Canadian Puma of Botany 67:34823485.Google Scholar
Dreyfus, B. L. & Dommergucs, Y. R. (1981). Nitrogen fixing nodules induced by Rhizobium on the stems of the tropical legume Sesbania rostrata. FEMS Microbiology Letters 10:313317.CrossRefGoogle Scholar
Flinn, J. C. & De Datta, S. K. (1984). Trends in irrigated rice yields under intensive cropping in Philippine research stations. Field Crops Research 9:115.CrossRefGoogle Scholar
George, T., Ladha, J. K., Garrity, D. P. & Buresh, R. J. (1994). Legumes as nitrate catch crops during the dry-to-wet transition in lowland rice cropping systems. Agronomy journal 86:267273.CrossRefGoogle Scholar
Grant, I. F., Tirol, A., Aziz, T. & Watanabe, I. (1983). Regulation of invertebrate grazers as a means to enhance biomass and nitrogen fixation of Cyanophyceac in wetland rice fields. Soil Science Society of America Journal 47:669675.CrossRefGoogle Scholar
Grant, I. F., Roger, P. A. & Watanabe, I. (1985). Effect of grazer regulation and algal inoculation on photodependent nitrogen fixation in a wetland rice field. Biology and Fertility of Soils 1:6172.CrossRefGoogle Scholar
Harada, T., Hayashi, R. & Chikamoto, A. (1964). Effect of physical pretreatment of the soils on the mineralization of native organic nitrogen in paddy soils. Journal of the Science of Soil and Manure, Japan 35:2124 (In Japanese.)Google Scholar
Inubushi, K. & Wada, H. (1987). Easily decomposable organic matter in paddy soils. VII. Effect of various pretreatments on N mineralization in submerged soils. Soil Science and Plant Nutrition 33: 567576.CrossRefGoogle Scholar
IRRI (1984) Annual Report for 1983. Manila, Philippines: International Rice Research Institute.Google Scholar
Kai, H. & Kawaguchi, S. (1977). The immobilization and release of nitrogen in soil and the chemical characteristics of nitrogen in those processes. In Proceedings of the International Seminar on Soil Environment and Fertility Management in Intensive Agriculture, 315323. Tokyo, Japan: Society of the Science of Soil and Manure.Google Scholar
Kanke, B. & Kanazawa, S. (1986). Effect of drainage on soil saccharides and microbial activities in poorly drained paddy fields. In Transactions of the 13th International Congress of Soil Science, Vol. 2, 594595. Hamburg, Germany.Google Scholar
Kieft, T. L., Soroker, E. & Firestone, M. K. (1987). Microbial biomass response to a rapid increase in water potential when dry soil is wetted. Soil Biology and Biochemistry, 19:119126.CrossRefGoogle Scholar
Khush, G. S. & Bennett, J. (eds) (1992). Nodulation and Nitrogen Fixation in Rice: Potential and Prospects. Manila, Philippines: International Rice Research Institute.Google Scholar
Koyama, T. (1971). Soil-plant studies on tropical rice. III. The effect of soil fertility status of nitrogen and its liberation upon the nitrogen utilization by rice plants in Bangkhen paddy soil. Soil Science and Plant Nutrition 17:210220.CrossRefGoogle Scholar
Koyama, T. (1981). The transformations and balance of nitrogen in Japanese paddy fields. Fertilizer Research 2:261278.CrossRefGoogle Scholar
Koyama, T. & App, A. (1979). Nitrogen balance in flooded rice soils. In Nitrogen and Rice, 95104. Manila, Philippines: International Rice Research Institute.Google Scholar
Koyama, T., Chammek, C. & Niamsrichand, N. (1973). Nitrogen application technology for tropical rice as determined by field experiments using 15N tracer technique. Tropical Agricultural Research Center Technical Bulletin No. 3. Japan: Ministry of Agriculture and Forestry.Google Scholar
Koyama, T., Shibuya, M., Tokuyasu, M., Shimomura, T., Ide, T. & Ide, K. (1977). Balance sheet and residual effects of fertilizer nitrogen in Saga paddy field. In Proceedings of the International Seminar on Soil Environment and Fertility Management in Intensive Agriculture, 289296. Tokyo, Japan: Society of the Science of Soil and Manure.Google Scholar
Kundu, D. K. & Pillai, K. G. (1992). Integrated nutrient supply system in rice and rice based cropping systems. Fertiliser News 37(4):3541.Google Scholar
Kundu, D. K. & Ladha, J. K. (1995). Efficient management of soil and biologically fixed nitrogen in intensively cultivated rice fields. Soil Biology and Biochemistry (in press).CrossRefGoogle Scholar
Kushari, D. P. & Watanabe, I. (1991). Differential responses of Azolla to phosphorus deficiency. I. Screening methods in quantity-controlled condition. Soil Science and Plant Nutrition 37:271282.CrossRefGoogle Scholar
Ladha, J. K. (1986). Studies on N2fixation by free-living and rice plant-associated bacteria in wetland rice field. Bionature 6(2):4758.Google Scholar
Ladha, J. K., Tirol, A. C., Daroy, M. L., Caldo, G., Ventura, W. & Watanabe, I. (1986). Plant-associated N2 fixation (C2H2-reduction) by five rice varieties, and relationship with plant growth characters as affected by straw incorporation. Soil Science and Plant Nutrition 32:91106.CrossRefGoogle Scholar
Ladha, J. K., Watanabe, I. & Saono, S. (1988). Nitrogen fixation by leguminous green manure and practices for its enhancement in tropical lowland rice. In Sustainable Agriculture: Green Manure in Rice Farming, 165183. Manila, Philippines: International Rice Research Institute.Google Scholar
Ladha, J. K., Pareek, R. P. & Becker, M. (1992). Stem nodulating legume-rhizobium symbiosis and its agronomic use in lowland rice. Advances in Soil Science 20:147192.CrossRefGoogle Scholar
Latorre, C., Lee, J. H., Spiller, H. & Shanmugam, K. T. (1986). Ammonium ion excreting cyanobactcrial mutants as a source of nitrogen for growth of rice: a feasibility study. Biotechnology Letters 8:507512.CrossRefGoogle Scholar
Liu, C. C. & Zheng, W. W. (1989). Azolla in China. Beijing: Agriculture Publishing House.Google Scholar
Lu, R. (1981). The fertility and fertilizer use of the important paddy soils of China. In Proceedings of the Symposium on Paddy Soil, 160–170 (Ed. by Institute of Soil Science, Academia Sinica). Beijing: Science Press and Springer-Verlag.Google Scholar
Maeda, K. & Shiga, H. (1978). Relationship between mineralization and nitrogen influenced by various conditions of submerged soils. Soil Science and Plant Nutrition 24:515524.CrossRefGoogle Scholar
Marumoto, T., Akai, H., Yoshida, T. & Harada, T. (1977). Drying effect on mineralization of microbial cells and their cell walls in soil and contribution of microbial cell walls as a source of decomposable soil organic matter due to drying. Soil Science and Plant Nutrition 23:919.CrossRefGoogle Scholar
Matsuguchi, T. (1979). Factors affecting heterotrophic nitrogen fixation in submerged rice soils. In Nitrogen and Rice, 207222. Manila, Philippines: International Rice Research Institute.Google Scholar
O'Toole, P. & Knowles, R. (1973). Efficiency of acetylene reduction (nitrogen fixation) in soil: effect of type and concentration of available carbohydrate. Soil Biology and Biochemistry 5:789797.CrossRefGoogle Scholar
Ponnamperuma, F. N. (1972). The chemistry of submerged soils. Advances in Agronomy 24:2996.CrossRefGoogle Scholar
Ponnamperuma, F. N. (1984). Straw as a source of nutrients for wetland rice. In Organic Matter and Rice, 117136. Manila, Philippines: International Rice Research Institute.Google Scholar
Ponnamperuma, F. N. (1985). Chemical kinetics of wetland rice soils relative to soil fertility. In Wetland Soils: Characterization, Classification and Utilization, 7180. Manila, Philippines: International Rice Research Institute.Google Scholar
Rao, V. R. (1976). Nitrogen fixation as influenced by moisture content, ammonium sulphate and organic sources in a paddy soil. Soil Biology and Biochemistry 8:445448.Google Scholar
Rao, V. R. (1978). Effect of carbon sources on asymbiotic nitrogen fixation in a paddy soil. Soil Biology and Biochemistry 10:319321.CrossRefGoogle Scholar
Roger, P. A. & Ladha, J. K. (1992). Biological N2 fixation in wetland rice fields: Estimation and contribution to nitrogen balance. Plant and Soil 141:4155.CrossRefGoogle Scholar
Roger, P. A., Kulasooriya, S. A., Tirol, A. C. & Craswell, E. T. (1981). Deep placement: A method of nitrogen fertilizer application compatible with algal nitrogen fixation in wetland rice soils. Plant and Soil 57:137142.CrossRefGoogle Scholar
Saito, Y., Kousaka, I. & Kamada, K. (1975). Physico-chemical changes of paddy soils after long term incorporation of rice straw. In Technical Bulletin of Aomori Agriculture Experimental Station 20:4251. (In Japanese.)Google Scholar
Santiago-Ventura, T., Bravo, M., Daez, C., Ventura, W., Watanabe, I. & App, A. A. (1986). Effects of N fertilizers, straw and dry fallow on the nitrogen balance of a flooded soil planted with rice. Plant and Soil 93:405411.CrossRefGoogle Scholar
Seneviratne, R. & Wild, A. (1985). Effect of mild drying on the mineralization of soil nitrogen. Plant and Soil 84:175179.CrossRefGoogle Scholar
Shi, S., Wen, Q. & Liao, H. (1980). The availability of nitrogen of green manures in relation to their chemical composition. Acta Pedologica Sinica 17:240246. (In Chinese.)Google Scholar
Shiga, H. & Ventura, W. (1976). Mineralization of soil organic nitrogen in paddy soils under field conditions in the Philippines. Soil Science and Plant Nutrition 22:387399.CrossRefGoogle Scholar
Soulides, D. A. & Allison, F. E. (1961). Effect of drying and freezing of soils on carbon dioxide production, available mineral nutrients, aggregation, and bacterial population. Soil Science 91:291298.CrossRefGoogle Scholar
Suzuki, M., Kamekawa, K., Sekiya, S. & Shiga, H. (1990). Effect of continuous application of organic or inorganic fertilizer for sixty years on soil fertility and rice yield in paddy field. In Transactions of the 14th International Congress of Soil Science, Vol. IV, 1419Kyoto, Japan.Google Scholar
Takai, Y. & Wada, H. (1977). Effects of water percolation on fertility of paddy soils. In Proceedings of the International Seminar on Soil Environment and Fertility Management in Intensive Agriculture, 216222. Tokyo, Japan: Society of the Science of Soil and Manure.Google Scholar
Takamura, Y., Tabuchi, T. & Kubota, H. (1977). Behaviour and balance of applied nitrogen and phosphorus under rice field conditions. In Proceedings of the International Seminar on Soil Environment and Fertility Management in Intensive Agriculture, 342349. Tokyo, Japan: Society of the Science of Soil and Manure.Google Scholar
van Gestel, M., Ladd, J. N. & Amato, M. (1991). Carbon and nitrogen mineralization from two soils of contrasting texture and microaggregate stability: Influence of sequential fumigation, drying and storage. Soil Biology and Biochemistry 23:313322.CrossRefGoogle Scholar
Wada, G., Shoji, S., Takahashi, J., Saito, K. & Shinbo, I. (1971). The fate of fertilizer nitrogen applied to the paddy field and its absorption by rice plant. Proceedings of the Crop Science Society of Japan 40:293.Google Scholar
Waring, S. A. & Bremner, J. M. (1964). Effect of soil mesh-size on the estimation of mineralizable nitrogen in soils. Nature 202:1141.CrossRefGoogle Scholar
Watanabe, I. (1985). Limiting factors in increasing N2-fixation in rice fields. In Biological Nitrogen Fixation in Africa: Proceedings of the 1st Conference of the African Association for Biological Nitrogen Fixation, 436464.Google Scholar
Watanabe, I. (1988). Problems in application of biological dinitrogen fixation in wetland rice. In Biotechnology of Nitrogen Fixation in the Tropics, 301–312 (Eds Shamsuddin, Z. H.Othman, W. M. W., Marziah, M. and Sundaram, J.). Malaysia: Universiti Pertanian.Google Scholar
Watanabe, I. & Liu, C. C. (1992). Improving nitrogen-fixing systems and integrating them into sustainable rice farming. Plant and Soil 141:5767.CrossRefGoogle Scholar
Watanabe, I. & Ramirez, C. (1984). Relationship between soil phosphorus availability and Azolla growth. Soil Science and Plant Nutrition 30:595598.Google Scholar
Watanabe, I., Espinas, C. R., Berja, N. S. & Alimagno, B. V. (1977). Utilization of Azolla-Anabaena complex as a nitrogen fertilizer for rice. IRRI Research Paper Series No. 11. Manila, Philippines: International Rice Research Institute.Google Scholar
Watanabe, I., Lee, K. K. & de Guzman, M. R. (1978). Seasonal change of N2-fixing rate in rice field assayed by in situ acetylene reduction technique. II. Estimate of nitrogen fixation associated with rice plants. Soil Science and Plant Nutrition 24:465471.CrossRefGoogle Scholar
Watanabe, I., de Guzman, M. R. & Cabrera, D. A. (1981). The effect of nitrogen fertilizer on N2-fixation in paddy field measured by in situ acetylene reduction assay. Plant and Soil 59:135139.CrossRefGoogle Scholar
Watanabe, I., Lapis, T. M., Oliveros, R. & Ventura, W. (1988). Improvement of phosphate fertilizer application to Azolla. Soil Science and Plant Nutrition 34:557569.CrossRefGoogle Scholar
Wei, W. X., Jin, G. Y. & Zhang, N. (1986). Preliminary report on Azolla hybridization studies. Bulletin of the Fujian Academy of Agricultural Sciences 1:7379. (In Chinese.)Google Scholar
Wilson, J. T. & Alexander, M. (1979). Effect of soil nutrient status and pH on nitrogen-fixing algae in flooded soils. Soil Science Society of America Journal 43:936939.CrossRefGoogle Scholar
Yatazawa, M. (1977). Agro-ecosystems in Japan. Agro-ecosystems 4:167179.Google Scholar
Yoo, I. D., Kimura, M., Wada, H. & Takai, Y. (1984.). Effects of environmental conditions on biological nitrogen fixation in paddy field. Japanese Journal of Soil Science and Plant Nutrition 55:460464.Google Scholar
Yoshida, T. & Padre, B. C. Jr. (1975). Effect of organic matter application and water regimes on the transformation of fertilizer nitrogen in a Philippine soil. Soil Science and Plant Nutrition 21:281292.CrossRefGoogle Scholar
Zhu, Z. (1990). Soil nitrogen. In Soils of China, 554–576 (Ed. by Institute of Soil Science, Academia Sinica). Beijing, China: Science Press.Google Scholar
Zhu, Z., Liao, X., Cai, G., Chen, R. & Wang, Z. (1983). On the improvement of the efficiency of nitrogen of chemical fertilizers and organic manures in rice production. Soil Science 135:3539.Google Scholar