Abstract
With the huge intensification of agriculture and the increasing awareness to human health and natural resources sustainability, there was a shift towards the development of environmental friendly N application approaches that support sustainable use of land and sustain food production.
The effectiveness of such approaches depends on their ability to synchronize plant nitrogen demand with its supply and the ability to apply favored compositions and dosages of N-species. They are also influenced by farming scale and its sophistication, and include the following key concepts: (i) Improved application modes such as split or localized (“depot”) application; (ii) use of bio-amendments like nitrification and urease inhibitors and combinations of (i) and (ii); (iii) use of controlled and slow release fertilizers; (iv) Fertigation-fertilization via irrigation systems including fully automated and controlled systems; and (v) precision fertilization in large scale farming systems. The paper describes the approaches and their action mechanisms and examines their agronomic and environmental significance. The relevance of the approaches for different farming scales, levels of agronomic intensification and agro-technical sophistication is examined as well.
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Feigin, A., Halevy, J., Irrigation-fertilisation-cropping management for maximum economic return and minimum pollution of ground water, Research Report Inst. Soil Water, ARO, The Volcani Center, Bet Dagan, 1989.
Smith, S. J., Schepers, J. S., Porter, L. K., Assessing and managing nitrogen losses to the environment, Adv. Soil Sci., 1990, 14: 1–45.
Fenn, L. B., Hossner, R. L., Ammonia volatilisation from ammonium and ammonium-forming fertilizers, Adv. Soil Sci., 1985, 1: 123–169.
Delgado, J. A., Mosier, A. R., Mitigation alternatives to decrease nitrous oxides emissions and urea-nitrogen loss and their effect on methane flux, Environ. Qual., 1996, 25: 1105–1111.
Smith, K. A., Effect of fertilizers on greenhouse gas fluxes: Mechanisms and Global Trends, in Third Int. Dahlia Greidinger Sym. on Fertilisation and The Environment, April 1997, Mortwedt, J. J. and Shaviv, A. Eds., Technion, Haifa, 1997.
Bockman, O. C., Kaarstad, O., Lie, O. H. et al., Agriculture and Fertilizers, Agricultural Group, Norsk Hydro, Oslo, 1990.
Shaviv, A., Controlled supply of fertilizers for increasing use efficiency and reducing pollution, in VIII International Colloquium on Optimization of plant nutrition, Lisabon, September, 1992 (eds. Fragoso et al.), Dordrecht: Kluwer Academic Pubs., 1993, 651–656.
Trenkel, M. E., Controlled Release and Stabilized Fertilizers in Agriculture, IFA, Paris, 1997.
Nelson, D.W., Effect of nitrogen excess on quality of food and fiber, in Nitrogen in Crop Production (ed. Hauck, R.D.), ASA, Madison WI, 1984, 643–661.
Shoji, S., Kanno, H., Use of polyolefin-coated fertilizers for increasing fertilizer efficiency and reducing nitrate leaching and nitrous oxide emissions, Fert. Res., 1994, 39: 147–52.
Shaviv, A., Advances in controlled release fertilizers. Advan. Agron., 2000, 71: 2–49.
Shaviv, A., Evaluation and Modeling of the Impact of Environmentally Friendly Fertilization Techniques” in Rubin, H. (ed.), Preserving the Quality of our Water Resources, New York: Springer Verlag, 2001.
Darrah, P. R., Nye, P. H., White, R.E., The effect of high solution concentration on nitrification rate in soil, Plant and Soil, 1987, 97: 37–45.
Yadvinder-Singh and Beauchamp, E.G., Nitrification inhibition with large urea granules, dicyandiamide, and low soil temperature. Soil Sci., 1987, 144: 412–419.
Shaviv, A., Control of nitrification rate by increasing ammonium concentrationm Fert. Res., 1988, 7: 177–188.
Glasscock, G. Shaviv, A. D Hagin, J., Nitrification Inhibitor-interaction with applied ammonium concentration, J. Plant Nut., 1995, 18: 105–116.
Hauck, R. D., Significance of nitrogen fertilizer microsite reactions in soil, in Nitrogen in Crop Production (ed. Hauck, R. D.), ASA, Madison, WI, 1984, 507–533.
Shaviv, A., Schnek, M., Reactions of a granulated super-phosphate and ammonium sulphate mixtures in calcareous soils, Geoderma, 1989, 44: 17–27.
Wang, F., Bear, J. Shaviv, A., Modeling simultaneous release, diffusion and nitrification of ammonium in the soil surrounding a granule or nest containing ammonium-fertilizer, European J. Soil Sci., 1998, 49: 351–364.
Nye, P. H., Acid-base changes in the rhizosphere, Adv. Plant Nutr., 1986, 2: 129–153.
Marshner, H., Mineral nutrition of higher plants” London: Academic Press, 1986.
Barak, P., Chen, Y., The evaluation of iron deficiency using a bioassay-type test, Soil Sci. Soc. Am. J., 1982, 46: 1019–1022.
Shaviv, A., Hagin, J., Correction of lime induced chlorosis by application of iron and potassium sulphatesm Fert. Res., 1987, 13: 161–167.
Hauck, R. D., Slow release and bio-inhibitor-amended nitrogen fertilizers, in Fertilizer technology and use”, (ed. Engelstad, O.P.), 3rd ed., SSSAMadison, WI. 1985, 293–322.
McCarty, G. W., Bremner, J. M., Persitence of effects of nitrification inhibitors added to soil, Commun. in Soil Sci. Plant Anal., 1990, 21: 639–648.
Zerulla, W., Kummer, K. F. Wisemeier, A. et al., The development and testing of new nitrification inhibitor, Proceeding No. 455. International fertilizer Society, York, 2000.
Shaviv, A., Mikkelsen, R. L., Slow release fertilizers for a safer environment maintaining high agronomic use efficiency, Fert. Res., 1993, 35: 1–12.
Bock, B. R., Agronomic differences between nitrate and ammoniacal nitrogen, in Proceedings of the 37th annual meeting, Fertilizer Industry round table, New Orleans, Louisiana, 1987, 105–110.
Hagin, J., Olsen, S. R., Shaviv, A., Review of interaction of ammonium-nitrate and potassium nutrition of crops, J. Plant Nutr., 1990, 13, 1211–1226.
Hendrickson, L. L., Keeney, D. R., Soil Biol. Biochem., 1979, 11: 51–55.
Zacherl, B., Amberger, A., Effect of the nitrification inhibitors dicyandiamide, nitrapyrin and thiourea on Nitrosomonas europaea. Fert. Res., 1990, 22: 37–44.
Biau, E. E., Zaiko, A. S., Muravin, E. A., Influence of systematic application of nitrification inhibitors on the marked fertilizer nitrogen balance in the pot experiment, Agrokhimiya, 2000, 3: 30–40.
Shaviv, A., Hagin, J., Neumann, P., Effects of nitrification inhibitor on efficiency of nitrogen utilization by wheat and millet, Commn. Soil Sci. Plant Anal., 1987, 18: 815–833.
Sachdev, M. S., Sachdev, P., Effect of dicyandiamide on the nitrification of fertilizer nitrogen, J. Nucl. Agric. Biol., 1995, 24: 145–153.
Puttanna, K., Gowda, N. M., Nanje, R. E., et al., Effect of concentration, temperature, moisture, liming and organic matter on the efficacy of the nitrification inhibitors benzotriazole, o-nitrophenol, m-nitroaniline and dicyandiamide, Nutr. Cycling Agroecosyst., 1999, 54: 251–257.
Malhi, S. S., Nybor, M., Methods of placement for increasing the efficiency of N fertilizers applied in the fall., Agron. J., 1985, 77: 27–32.
Orphanos, P. I., Inhibition of ammonium sulfate nitrification by methylpyrazol in a highly calcareous soil, Plant Soil, 1992, 143: 145–7.
Blaise, D., Amberger, A. Tucher, S. von, Efficacy of CMP [1-carboxamide, 3-(5)-methylpyrazole] and DCD (dicyandiamide) as nitrification inhibitor, J. Indian Soc. Soil Sci., 1999, 47: 80–84.
Zerulla, W., Erhardt, K., Dressel, J., Horchler, K. et al., DMPP, a new nitrification inhibitor for agriculture and horticulture, VDLUFA-Schriftenr., 1999, 52: 525–528.
Watson, C. J., Urease activity and inhibition principles and practice, Proceeding No. 454. International fertilizer Society, York, 2000.
Bremner, J. M., Chai, H. S., Effects of phosphoroamides on ammonia volatilization and nitrite accumulation in soils treated with urea, Biol. Fertil. Soils, 1989, 8: 227–30.
Phongpan, S., Freney, J.R. Keerthisinghe, D.G. et al., Use of urease inhibitors to reduce ammonia loss from broadcast urea and increase grain yield of flooded rice in Thailand, Soil Sci. Plant Nutr. (Tokyo), 1997, 43: 1057–1060.
Montemurro, F., Capotorti, G. Lacertosa, D. et al., Effects of urease and nitrification inhibitors application on urea fate in soil and nitrate accumulation in lettuce, J. Plant Nutr, 1998, 21: 245–252.
Xu, X. K., Zhou, L. K., Wang, Z. J. et al., Fate of urea-15N in a soil-wheat system as influenced by urease inhibitor hydroquinone and nitrification inhibitor dicyandiamide, Plant and Soil, 2000, 220: 261–270.
Nedan, S., Control of nitrification rate by ammonium and inhibitors, MSc Thesis, Agric. Eng. Technion (in Hebrew, Tables and Figures in English), 1990.
Shaviv, A., S., Mixed N-P granulated fertilizer amended with nitrification inhibitors: Less pollution and higher efficiency, Extended Abstract, 7th Nitrogen workshop, Edinburgh, 1992.
Peoples, M. B., Freney, J. R., Moiser, A. R., Minimizing gaseous losses of nitrogen, in Nitrogen Fertilization in the Environment” (ed. Bacon, P. E.), New York: Marcel Dekeker Inc., 1995, 565–601.
Du, Changwen, Zhou, Jianmin, Progress in study of controlled-release fertilizers (CRF), Turang (Nanjing, China) 2002, 34(3): 127–133.
Shaviv, A., Plant response and environmental aspects as affected by rate and pattern of nitrogen release from controlled release N fertilizers, in Progress in Nitrogen Cycling Studies (eds. Van Cleemput et al.), Dordrecht: Kluwer Academ Pub., 1996, 285–291.
Shaviv, A., Preparation methods and release mechanisms of controlled release fertilizers: Agronomic efficiency and environmental significance, International Fertilizer Society, York, UK, Proceedings N 1999, 431: 1–35.
Hagin, J., Harrison, R., Non-acidulated and partially-acidulated phosphate rocks as controlled release P fertilizers, Fert. Res., 1993, 35: 25–31.
Shoji, S., Gandeza, A.T., Controled Release Fertilizers with Polyolefin Resin Coating, Sendai: Konno Printing Co., 1992.
Allen, S. E., Slow-release nitrogen fertilizers, in Nitrogen in crop production (ed. Hauck, R.D.), Madison: WI., 1984, 195–206.
Bar-Yosef, B., Advances in fertigation. Advan. Agron., 1999, 65: 1–77.
Hagin, J., Lowengart-Aycicegi, A., Fertigation-State of the art, The International Fertilizer Society, York, Proceedings No 429, 1999.
Bucks, D. A., Historical development in micro-irrigation, Proc. 5th Int. Microirrigation Cong. Orlando, FL, 1995, 1–5.
Steffen, K. L., Dann, M. S., Harper, J. K. et al., Evaluation of the initial season for implementation of four tomato production systems, J.A. Soc. Hort. Sci., 1995, 120: 48–156.
Sonneveld, C., Fertigation in greenhouse industry, in Dahlia Greidinger Int. Symposium on Fertigation. Technion, Haifa Israel, 1995, 121–140.
Sonneveld, C., D’Welles, G. W. H., Yield and quality of rockwool-grown tomatoes as affected by variations in EC-value and climatic conditions, Plant and Soil, 1988, 111: 37–42.
Hagin, J., G. Segelman, Shaviv, A., Strategy for development of fertilizer solutions for greenhouse tomatoes, Fertilizer Research, 1990, 26(1–3): 3–60.
Eiswenstadt, Y. Wallach, R., Shaviv, A., Water saving and reduced nutrieny pollutionin greenhouse production, in Proc. # 529 Int. Fer. Soc. Nutrient, Substrate and Water Management in Protected Cropping Systems, Izmir December 2003, IFS.
Raviv, M., Krasnovsky, A., Medina, S. et al., Assessment of various control strategies for recirculation of greenhouse effluents under semi-arid, J. Hortic. Sci. Biotechnol., 1998, 73: 485–491.
Langlais, C., Deniel, F., Wolbert, D. et al., Study of the treatment and the recirculation of water from soil-less horticulture, Rev. Sci. Eau., 2000, 13: 5–12.
De Kreij, C., Latest insights into water and nutrient control in soilless cultivation, Acta Horticulturae, 1995, 408(International Seminar on Soilless Cultivation Technology for Protected Crops in Mild Winter Climates, 1993), 47–61.
Avidan, A., Recycling of the drainage water in Israel-State of the Art, in Abstracts-Annual meeting on Automation, Control and Recycling in Greenhouses, 1997, Volcani Center (in Hebrew).
Jung, V., Chimuka, L., Jonsson, J.-A. et al., Supported liquid membrane extraction for identification of phenolic compounds in the nutrient solution of closed hydroponic growing systems for tomato, Analytica Chimica Acta, 2002, 474(1–2): 49–57.
Graves, C. J., The nutrient film technique, 1983, Hort. Rev. 5: 1–44.
Roblin, P., Barrow, D. A., Microsystems technology for remote monitoring and control in sustainable agricultural practices, J. Environmental Monitoring, 1983, 2(5): 385–392.
Robert, P. C., Precision agriculture: a challenge for crop nutrition management, Plant and Soil, 2002, 247(1): 143–149.
Cook, S. E., Bramley, R. G. V., Coping with variability in agricultural production-implications for soil testing and fertilizer management, Commn. in Soil Sci. Plant Anal., 2000, 31(11–14): 1531–1551.
Haneklaus, Silvia, Schnug, Ewald., Decision-making strategies for the variable-rate application of compound fertilizers, Commn. in Soil Sci. Plant Anal., 2000, 31(11–14): 1863–1873.
Shey, U., Kamp, T., Ruser, R. et al., The potential pf precision farming for reducing the emissions of nitrous oxide from agricultural field in soutjern germany, in Transport and Chemivals Transformation in the Troposphere, Proc. of EUROTRAC Symp. (ed. Midgley et al.), Belgium: Springer-Verlag, 2001, 1062–1066.
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Shaviv, A. Environmental friendly nitrogen fertilization. Sci. China Ser. C.-Life Sci. 48 (Suppl 2), 937–947 (2005). https://doi.org/10.1007/BF03187132
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DOI: https://doi.org/10.1007/BF03187132