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Plant, Soil and Environment

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2014

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Vasak, F.

Influence of Long-Term Fertilizer Application on Changes of the Content of Mehlich-3 Estimated Soil Macronutrients

Abstract Views :83 | PDF Views:46

Authors

M. Kulhanek ¹, J. Balik ², J. Cerny ², F. Vasak ², S. Shejbalova ²

Affiliations
1 Department of Agro-Environmental Chemistry and Plant Nutrition, Food and Natural Resources, Czech University of Life Sciences Prague, Kamycka 129, 165 21 Praha 6-Suchdol, CZ
2 Department of Agro-Environmental Chemistry and Plant Nutrition, Food and Natural Resources, Czech University of Life Sciences Prague, Prague, CZ

Source

Plant, Soil and Environment, Vol 60, No 4 (2014), Pagination: 151-157

Abstract

The aim of this work is to evaluate the changes of Mehlich 3 - P, K, Ca and Mg contents in soil during a long-term field experiments with sewage sludge, farmyard manure (FYM) and mineral NPK (NPK) application, compared to the control non-fertilized treatment. The experiment was established at the Humpolec and Suchdol sites (Czech Republic). Potatoes, wheat and barley were grown in crop rotation. Fertilizing system was based on the same nitrogen dose of 330 kg N/ha per one crop rotation. Archive soil samples from the beginning of the experiment (1996) and from the end of each year's crop rotation (1999, 2002, 2005, 2008 and 2011) were analyzed. In spite of the different soil-climatic conditions of the studied sites, very similar tendencies of P, K, Ca and Mg contents changes after the fertilizing systems used were observed in the soil. In case of the same nitrogen dose (330 kg N/ha), sewage sludge appeared to be better source of bioavailable soil phosphorus compared to the farmyard manure and NPK. On the contrary, FYM was a better source of bioavailable potassium and magnesium, despite the lower total magnesium content in FYM. The NPK treatment was the best long-term source of bioavailable potassium.

Keywords

Soil, Sewage Sludge, Farmyard Manure, Mineral NPK, Bioavailable P, K, Ca, Mg.

Full Text

References

Alfaro M.A., Jarvis S.C., Gregory P.J. (2004): Factors affecting potassium leaching in different soils. Soil Use and Management, 20: 182-189.

Antolin M.C., Pascual I., Garcia C., Polo A., Sanchez-Diaz M. (2005): Growth, yield and solute content of barley in soils treated with sewage sludge under semiarid Mediterranean conditions. Field Crops Research, 94: 224-237.

Balik J., Pavlikova D., Vanek V., Kulhanek M., Kotkova B. (2007): The influence of long-term sewage sludge application on the activity of phosphatases in the rhizosphere of plants. Plant, Soil and Environment, 53: 375-381.

Barzegar A.R., Yousefi A., Daryashenas A. (2002): The effect of addition of different amounts and types of organic materials on soil physical properties and yield of wheat. Plant and Soil, 247: 295-301.

Bhattacharyya R., Chandra S., Singh R.D., Kundu S., Srivastva A.K., Gupta H.S. (2007): Long-term farmyard manure application effects on properties of a silty clay loam soil under irrigated wheat-soybean rotation. Soil and Tillage Research, 94: 386-396.

Blume H.-P., Brummer G.W., Schwertmann U., Horn R., Knabner I.K. (2002): Scheffer/Schachtschabel: Textbook of Soil Scientist. Spektrum Akademischer Verlag, Stuttgart, 607. (In German)

Bozkurt M.A., Yarilgac T. (2003): The effects of sewage sludge applications on the yield, growth, nutrition and heavy metal accumulation in apple trees growing in dry conditions. Turkish Journal of Agriculture and Forestry, 27: 285-292.

Cerny J., Balik J., Kulhanek M., Casova K., Nedved V. (2010): Mineral and organic fertilization efficiency in long-term stationary experiments. Plant, Soil and Environment, 56: 28-36.

Chowaniak M., Gondek K. (2009): Changes in the available magnesium and zinc contents of soils after the application of sewage sludges and sewage sludge - peat mixtures. Journal of Central European Agriculture, 10: 79-87.

Christie P., Easson D.L., Picton J.R., Love C.P.S. (2001): Agronomic value of alkaline-stabilized sewage biosolids for spring barley. Agronomy Journal, 93: 144-151.

Citak S., Sonmez S. (2011): Effects of different organic manure applications on the macro nutrient contents of soil in different growing seasons. Journal of Agricultural Science and Technology, 5: 157-163.

Coker E.G., Carlton-Smith C.H. (1986): Phosphorus in sewage sludges as a fertilizer. Waste Management and Research, 4: 303-319.

Hejcman M., Kunzova E., Srek P. (2012): Sustainability of winter wheat production over 50 years of crop rotation and N, P and K fertilizer application on illimerized luvisol in the Czech Republic. Field Crops Research, 139: 30-38.

Huang X.L., Chen Y., Shenker M. (2012): Dynamics of phosphorus phytoavailability in soil amended with stabilized sewage sludge materials. Geoderma, 170: 144-153.

Johnston A.E. (1997): The value of long-term field experiments in agricultural, ecological, and environmental research. Advances in Agronomy, 59: 291-333.

Kidd P.S., Dominguez-Rodriguez M.J., Diez J., Monterroso C. (2007): Bioavailability and plant accumulation of heavy metals and phosphorus in agricultural soils amended by long-term application of sewage sludge. Chemosphere, 66: 1458-1467.

Kulhanek M., Balik J., Cerny J., Vanek V. (2009): Evaluation of phosphorus mobility in soil using different extraction methods. Plant, Soil and Environment, 55: 267-272.

Liu E., Yan Ch., Mei X., He W., Bing S.H., Ding L., Liu Q., Liu S., Fan T. (2010): Long-term effect of chemical fertilizer, straw, and manure on soil chemical and biological properties in northwest China. Geoderma, 158: 173-180.

Mehlich A. (1984): Mehlich 3 soil test extractant: A modification of Mehlich 2 extractant. Communications in Soil Science and Plant Analysis, 15: 1409-1416.

Mosquera-Losada M.R., Munoz-Ferreiro N., Rigueiro-Rodriguez A. (2010): Agronomic characterisation of different types of sewage sludge: Policy implications. Waste Management, 30: 492-503.

Petersen J. (2003): Nitrogen fertilizer replacement value of sewage sludge, composted household waste and farmyard manure. Journal of Agricultural Science, 140: 169-182.

Petersen S.O., Petersen J., Rubaek G.H. (2003): Dynamics and plant uptake of nitrogen and phosphorus in soil amended with sewage sludge. Applied Soil Ecology, 24: 187-195.

Pierson-Wickmann A.C., Aquillina L., Weyer C., Molenat J., Lischeid G. (2009): Acidification processes and soil leaching influenced by agricultural practices revealed by strontium isotopic ratios. Geochimica et Cosmochimica Acta, 73: 4688-4704.

Powlson D.S., Jenkinson D.S., Pruden G., Johnson A.E. (1985): The effect of straw incorporation on the uptake of nitrogen by winter wheat. Journal of the Science of Food and Agriculture, 36: 26-30.

Schroder J.L., Zhang H., Richards J.R. (2009): Interlaboratory validation of the Mehlich 3 method as a universal extractant for plant nutrients. Journal of AOAC International, 92: 995-1008.

Sims J.T., Maguire R.O., Leytem A.B., Gartley K.L., Pautler M.C. (2002): Evaluation of Mehlich 3 as an agri-environmental soil phosphorus test for the mid Atlantic United States of America. Soil Science Society of America Journal, 66: 2016-2022.

Thomsen I.K., Jensen E.S. (1994): Recovery of nitrogen by spring barley following incorporation of 15N-labelled straw and catch crop material. Agriculture, Ecosystems and Environment, 49: 115-122.

Troeh F.R., Thompson L.M. (2005): Soils and Soil Fertility. 6^th Edition. Blackwell Publishing Professional, Iowa, 489.

Vanek V., Balik J., Cerny J., Pavlik M., Pavlikova D., Tlustos P., Valtera J. (2012): Nutrition of Horticultural Crops. Academia, Praha, 568. (In Czech)

Warman P.R., Termeer W.C. (2005a): Evaluation of sewage sludge, septic waste and sludge compost applications to corn and forage: Ca, Mg, S, Fe, Mn, Cu, Zn and B content of crop and soils. Bioresource Technology, 96: 1029-1038.

Warman P.R., Termeer W.C. (2005b): Evaluation of sewage sludge, septic waste and sludge compost applications to corn and forage: Yields and N, P and K content of crops and soils. Bio-resource Technology, 96: 955-961.

Wen G., Bates T.E., Voroney R.P., Winter J.P., Schellenberg M.P. (1999): Influence of application of sewage sludges, and sludge and manure composts on plant Ca and Mg concentration and soil extractability in field experiments. Nutrient Cycling in Agroecosystems, 55: 51-61.

Zhang H., Kaiuki S., Schroder J.L., Payton M.E., Focht C. (2009): Interlaboratory validation of the Mehlich 3 method for extraction of plant-available phosphorus. Journal of AOAC International, 92: 91-102.

Nitrogen Efficiency of Spring Barley in Long-Term Experiment

Abstract Views :78 | PDF Views:45

Authors

S. Shejbalova ¹, J. Cerny ², F. Vasak ², M. Kulhanek ², J. Balik ²

Affiliations
1 Department of Agro-Environmental Chemistry and Plant Nutrition, Food and Natural Resources, Czech University of Life Sciences Prague, Kamycka 129 , 165 21 Prague 6 - Suchdol, Prague, CZ
2 Department of Agro-Environmental Chemistry and Plant Nutrition, Food and Natural Resources, Czech University of Life Sciences Prauge, Prauge, CZ

Source

Plant, Soil and Environment, Vol 60, No 7 (2014), Pagination: 291-296

Abstract

The aim of this study was to evaluate nitrogen (N) efficiency from different organic and mineral fertilizers applied to the spring barley. Dry matter yield, N content and N uptake of spring barley from 16 years of experiments at two sites in the Czech Republic with different soil and climatic conditions were analyzed. For assessing of nitrogen efficiency nitrogen utilization efficiency (NUtE, kg/kg), recovery efficiency of applied N (%), agronomic efficiency of applied N (kg/kg) and summary N balances (ΣΔN, kg/ha) were observed. Six fertilization treatments were utilized: no fertilization (control); sewage sludge; farmyard manure (FYM); N in mineral fertilizers (N); NPK in mineral fertilizers (NPK) and N in mineral fertilizers + straw (N + ST). Yields were about 68% higher at NPK (S1 site) and 55% at N + ST (S2 site) in comparison with control. The highest NUtE was recorded at both locations after application of FYM. Higher NUtE from mineral fertilizers was obtained at low productive S1 site. At both sites a trend of decreasing ΣΔN over time was observed. At both sites a trend of decreasing negative N balance was observed. At lower productive site the decline of N balance was minimized for mineral fertilizers treatments in last experimental years. At higher productive site the differences between treatments with mineral nitrogen and control were lower and the decline of N balance continued over all 16 years of experiment duration.

Keywords

N Balance, Mineral Fertilizers, Organic Fertilizers, Yield, Nitrogen Utilization.

Full Text

References

Anbessa Y., Juskiw P. (2012): Review: Strategies to increase nitrogen use efficiency of spring barley. Canadian Journal of Plant Science, 92: 617-625.

Andersson A., Holm L. (2011): Effects of mild temperature stress on grain quality and root and straw nitrogen concentration in malting barley cultivars. Journal of Agronomy and Crop Science, 197: 466-476.

Angas P., Lampurlanes J., Cantero-Martinez C. (2006): Tillage and N fertilization: Effects on N dynamics and barley yield under semiarid Mediterranean conditions. Soil and Tillage Research, 87: 59-71.

Balasubramanian V., Alves B., Aulakh M., Bekunda M., Cai Z., Drinkwater L., Mugendi D., Kessel C. van, Oenema O. (2004): Crop, environmental, and management factors affecting nitrogen use efficiency. In: Mosier A., Syers J.K., Freney J.R. (eds.): Agriculture and the Nitrogen Cycle. Scope, USA.

Bingham I.J., Blake J., Foulkes M.J., Spink J. (2007): Is barley yield in the UK sink limited?: I. Post-anthesis radiation interception, radiation-use efficiency and source-sink balance. Field Crops Research, 101: 198-211.

Bingham I.J., Karley A.J., White P.J., Thomas W.T.B., Russell J.R. (2012): Analysis of improvements in nitrogen use efficiency associated with 75 years of spring barley breeding. European Journal of Agronomy, 42: 49-58.

Cantero-Martinez C., Angas P., Lampurlanes J. (2003): Growth, yield and water productivity of barley (Hordeum vulgare L.) affected by tillage and N fertilization in Mediterranean semiarid, rainfed conditions of Spain. Field Crops Research, 84: 341-357.

Cassman K.G., Dobermann A., Walters D.T. (2002): Agroecosystems, nitrogen-use efficiency, and nitrogen management. Ambio: A Journal of the Human Environment, 31: 132-140.

Cerny J., Balik J., Kulhanek M., Casova K., Nedved V. (2010): Mineral and organic fertilization efficiency in long-term stationary experiments. Plant, Soil and Environment, 56: 28-36.

Cossani C.M., Slafer G.A., Savin R. (2009): Yield and biomass in wheat and barley under a range of conditions in a Mediterranean site. Field Crops Research, 112: 205-213.

Delogu G., Cattivelli L., Pecchioni N., de Falcis D., Maggiore T., Stanca A.M. (1998): Uptake and agronomic efficiency of nitrogen in winter barley and winter wheat. European Journal of Agronomy, 9: 11-20.

Dobermann A.R. (2005): Nitrogen Use Efficiency - State of the Art. University of Nebraska, Lincoln.

FAO (2011): FAOSTAT Database Agricultural Production. Available at http://apps.fao.org. Food and Agricultural Organization of the United Nations

Hejcman M., Kunzova E., Srek P. (2012): Sustainability of winter wheat production over 50 years of crop rotation and N, P and K fertilizer application on illimerized luvisol in the Czech Republic. Field Crops Research, 139: 30-38.

Hejcman M., Berkova M., Kunzova E. (2013): Effect of long-term fertilizer application on yield and concentrations of elements (N, P, K, Ca, Mg, As, Cd, Cu, Cr, Fe, Mn, Ni, Pb, Zn) in grain of spring barley. Plant, Soil and Environment, 59: 329-334.

Kunzova E., Hejcman M. (2009): Yield development of winter wheat over 50 years of FYM, N, P and K fertilizer application on black earth soil in the Czech Republic. Field Crops Research, 111: 226-234.

Ladha J.K., Pathak H., Krupnik T.J., Six J., van Kessel C. (2005): Efficiency of fertilizer nitrogen in cereal production: Retrospects and prospects. Advances in Agronomy, 87: 85-156.

Liu J., Liu H., Huang S., Yang X., Wang B., Li X., Ma Y. (2010): Nitrogen efficiency in long-term wheat-maize cropping systems under diverse field sites in China. Field Crops Research, 118: 145-151.

Mengel K., Hutsch B., Kane Y. (2006): Nitrogen fertilizer application rates on cereal crops according to available mineral and organic soil nitrogen. European Journal of Agronomy, 24: 343-348.

Moll R.H., Kamprath E.J., Jackson W.A. (1982): Analysis and interpretation of factors which contribute to efficiency to nitrogen utilization. Agronomy Journal, 74: 562-564.

Montemurro F., Maiorana M., Ferri D., Convertini G. (2006): Nitrogen indicators, uptake and utilization efficiency in a maize and barley rotation cropped at different levels and sources of N fertilization. Field Crops Research, 99: 114-124.

Pettersson C.G., Eckersten H. (2007): Prediction of grain protein in spring malting barley grown in northern Europe. European Journal of Agronomy, 27: 205-214.

Sedlar O., Balik J., Kozlovsky O., Peklova L., Kubesova K. (2011): Impact of nitrogen fertilizer injection on grain yield and yield formation of spring barley (Hordeum vulgare L.). Plant, Soil and Environment, 57: 547-552.

Snyder C.S. (2009): Nitrogen use efficiency: Global challenges, trends and the future. Nutrient use efficiency. In: Proceedings of the XVIII Latin American Congress of Soil Science, 16-20^th November 2009, Costa Rica, 10-17.

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