Hostname: page-component-586b7cd67f-r5fsc Total loading time: 0 Render date: 2024-11-28T02:34:12.413Z Has data issue: false hasContentIssue false

Organic management and legume presence maintained phosphorus bioavailability in a 17-year field crop experiment

Published online by Cambridge University Press:  31 October 2013

Courtney Gallaher
Affiliation:
Department of Geography, Northern Illinois University, DeKalb, IL 60115, USA.
Sieglinde S. Snapp*
Affiliation:
Department of Plant, Soil and Microbial Sciences, W.K. Kellogg Biological Station, Michigan State University, 3700 E. Gull Lake Road, Hickory Corners, MI 49060, USA.
*
*Corresponding author: [email protected]

Abstract

Legumes have been shown to enhance bioavailability of phosphorus (P) from sparingly soluble pools, yet this functional trait remains underutilized in agriculture, and is untested at decadal scales. Management and legume presence effects on temporal soil properties were evaluated in a 17-year field crop experiment using soil samples collected in 1992, 2000 and 2006. Management systems compared included: (1) conventional corn–soybean–wheat rotation (C–S–W), (2) organic (C–S–W+red clover), (3) alfalfa and (4) early successional field. To evaluate the effects of long-term management versus recent management (residues and P fertilizer) on P and bio-availability to soybean, subplots of soybean were established with and without P-fertilizer (30 kg P ha−1), and compared to subplots and main plot with the long-term system. We evaluated soil properties (C, total P, Bray extractable inorganic P, particulate organic matter phosphorus) and soybean P uptake, biomass and yield. Recent fertilizer P inputs had no detectable influence on soil P, and total soil P stayed stable at ~350 mg P kg−1, whereas inorganic P (Pi) declined from an initial value of 54 to an average of 35 mg P kg−1. A P balance was constructed and showed a net loss of −96.7 kg P ha−1 yr−1 for the organic system, yet Bray-Pi and soybean P uptake were maintained under organic production at similar levels to the conventional, fertilized system. Particulate organic matter P was 57, 82 and 128% higher in organic, alfalfa and successional treatments, respectively, compared to conventional. A similar pattern was observed for soil C, soybean yield and bioavailable P, which were 20–50% higher in the organic, alfalfa and successional systems relative to conventional. This study provides evidence that long-term management history influences bioavailability of P.

Type
Research Papers
Copyright
Copyright © Cambridge University Press 2013 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1Blake, L., Mercik, S., Koerschens, M., Moskal, S., Poulton, P.R., Goulding, K.W.T., Weigel, A., and Powlson, D.S. 2000. Phosphorus content in soil, uptake by plants and balance in three European long-term field experiments. Nutrient Cycling in Agroecosystems 56:263275.Google Scholar
2Daroub, S.H., Ellis, B.G., and Robertson, G.P. 2001. Effect of cropping and low-chemical input systems on soil phosphorus fractions. Soil Science 166:281291.Google Scholar
3Oehl, F., Oberson, A., Tagmann, H.U., Besson, J.M., Dubois, D., Mäder, P., Roth, H.R., and Frossard, E. 2002. Phosphorus budget and phosphorus availability in soils under organic and conventional farming. Nutrient Cycling in Agroecosystems 62:2535.Google Scholar
4Wortman, S.E., Galusha, T.D., Mason, S.C., and Francis, C.A. 2011. Soil fertility and crop yields in long-term organic and conventional cropping systems in Eastern Nebraska. Renewable Agriculture and Food Systems 26:117.Google Scholar
5Drinkwater, L.E. and Snapp, S.S. 2007. Nutrients in agroecosystems: Rethinking the management paradigm. Advances in Agronomy 92:163186.Google Scholar
6Li, L., Li, S.M., Sun, J.H., Zhou, L.L., Bao, X.G., Zhang, H.G., and Zhang, F.S. 2007. Diversity enhances agricultural productivity via rhizosphere phosphorus facilitation on phosphorus-deficient soils. Proceedings of the National Academy of Sciences of the United States of America 104:1119211196.Google Scholar
7Ae, N., Arihara, J., Okada, K., Yoshihara, T., and Johansen, C. 1990. Phosphorus uptake by pigeon pea and its role in cropping systems of the Indian subcontinent. Science 248:477480.Google Scholar
8Masaoka, Y., Kojima, M., Sugihara, S., Yoshihara, T., Koshino, M., and Ichihara, A. 1993. Dissolution of ferric phosphate by alfalfa (Medicago-sativa L) root exudates. Plant and Soil 155:7578.Google Scholar
9Hinsinger, P. 2001. Bioavailability of soil inorganic P in the rhizosphere as affected by root-induced chemical changes: A review. Plant and Soil 237:173195.Google Scholar
10Walker, T.W. and Syers, J.K. 1976. The fate of phosphorus during pedogenesis. Geoderma 15:119.Google Scholar
11Bundy, L.G. and Sturgul, S.J. 2001. A phosphorus budget for Wisconsin cropland. Journal of Soil and Water Conservation 56:243249.Google Scholar
12Gosling, P. and Shepherd, M. 2005. Long-term changes in soil fertility in organic arable farming systems in England, with particular reference to phosphorus and potassium. Agriculture Ecosystems and Environment 105:425432.CrossRefGoogle Scholar
13Oberson, A., Fardeau, J.C., Besson, J.M., and Sticher, H. 1993. Soil-phosphorus dynamics in cropping systems managed according to conventional and biological agricultural methods. Biology and Fertility of Soils 16:111117.Google Scholar
14Gahoonia, T.S. and Nielsen, N.E. 1992. The effects of root-induced pH changes on the depletion of inorganic and organic phosphorus in the rhizosphere. Plant and Soil 143:185191.Google Scholar
15Riley, D. and Barber, S.A. 1971. Effect of ammonium and nitrate fertilization on phosphorus uptake as related to root-induced pH changes at root-soil interface. Soil Science Society of America Proceedings 35:301306.Google Scholar
16Lipton, D.S., Blanchar, R.W., and Blevins, D.G. 1987. Citrate, malate, and succinate concentration in exudates from P-sufficient and P-stressed Medicago sativa L. seedlings. Plant Physiology 85:315317.Google Scholar
17Cavigelli, M.A. and Thien, S.J. 2003. Phosphorus bioavailability following incorporation of green manure crops. Soil Science Society of America Journal 67:11861194.Google Scholar
18Ohwaki, Y. and Hirata, H. 1992. Differences in carboxylic acid exudation among P-starved leguminous crops in relation to carboxylic acid contents in plant tissues and phospholipid level in roots. Soil Science & Plant Nutrition 38:235243.Google Scholar
19Cassman, K.G., Whitney, A.S., and Stockinger, K.R. 1980. Root-growth and dry-matter distribution of soybean as affected by phosphorus stress, nodulation, and nitrogen source. Crop Science 20:239244.Google Scholar
20Sanyl, S.K. and De Datta, S.K. 1991. Chemistry of phosphorus transformations in soil. Advances in Soil Science 16:1120.Google Scholar
21Bray, R.H. 1945. Determination of total, organic, and available forms of phosphorus in soil. Soil Science 59:3945.Google Scholar
22Mehlich, A. 1984. Mehlich no. 3 extractant: A modification of Mehlich no. 2 extractant. Communications in Soil Science and Plant Analysis 15:14091416.Google Scholar
23Beedy, T.L., Snapp, S.S., Akinnifesi, F.K., and Sileshi, G.W. 2010. Impact of Gliricidia sepium intercropping on soil organic matter fractions in a maize-based cropping system. Agriculture Ecosystems and Environment 138:139146.Google Scholar
24Conteh, A., Blair, G.J., and Rochester, I.J. 1998. Soil organic carbon fractions in a Vertisol under irrigated cotton production as affected by burning and incorporating cotton stubble. Australian Journal of Soil Research 36:655668.Google Scholar
25Alvarez, R. and Alvarez, C.R. 2000. Soil organic matter pools and their associations with carbon mineralization kinetics. Soil Science Society of America Journal 64:184189.Google Scholar
26Franzluebbers, A.J. and Stuedemann, J.A. 2002. Particulate and non-particulate fractions of soil organic carbon under pastures in the Southern Piedmont USA. Environmental Pollution 116:S53S62.CrossRefGoogle ScholarPubMed
27Salas, A.M., Elliott, E.T., Westfall, D.G., Cole, C.V., and Six, J. 2003. The role of particulate organic matter in phosphorus cycling. Soil Science Society of America Journal 67:181189.Google Scholar
28Crum, J.R. and Collins, H.P. 1995. Kellogg Biological Station Soil Description. Kellogg Biological Station—Michigan State University. Available at Web site: http://lter.kbs.msu.edu/research/site-description-and-maps/soil-description/. (updated 1995, cited January 22, 2009).Google Scholar
29LTER. 2009. LTER Data Catalog. Kellogg Biological Station, Michigan State University. Available at Web site: http://lter.kbs.msu.edu/datatables. (updated 2009, cited January 22, 2009).Google Scholar
30Gelfand, I., Snapp, S.S., and Robertson, G.P. 2010. Energy efficiency of conventional, organic, and alternative cropping systems for food and fuel at a site in the US Midwest. Environmental Science and Technology 44:40064011.Google Scholar
31Kuo, S. 1996. Phosphorus. In Sparks, D.L. (ed.). Methods of Soil Analysis: Chemical Methods. 3rd ed.Soil Science Society of America, Madison, WI. p. 869920.Google Scholar
32Grandy, A.S. and Robertson, G.P. 2007. Land-use intensity effects on soil organic carbon accumulation rates and mechanisms. Ecosystems 10:5974.Google Scholar
33Taylor, M.D. 2000. Determination of total phosphorus in soil using simple Kjeldahl digestion. Communications in Soil Science and Plant Analysis 31:26652670.Google Scholar
34Vitousek, P.M., Naylor, R., Crews, T., David, M.B., Drinkwater, L.E., Holland, E., Johnes, P.J., Katzenberger, J., Martinelli, L.A., Matson, P.A., Nziguheba, G., Ojima, D., Palm, C.A., Robertson, G.P., Sanchez, P.A., Townsend, A.R., and Zhang, F.S. 2009. Nutrient imbalances in agricultural development. Science 324:15191520.Google Scholar
35Heckman, J.R., Sims, J.T., Beegle, D.B., Coale, F.J., Herbert, S.J., Bruulsema, T.W., and Bamka, W.J. 2003. Nutrient removal by corn grain harvest. Agronomy Journal 95:587591.CrossRefGoogle Scholar
36Takahashi, S. and Anwar, M.R. 2007. Wheat grain yield, phosphorus uptake and soil phosphorus fraction after 23 years of annual fertilizer application to an Andosol. Field Crops Research 101:160171.CrossRefGoogle Scholar
37Six, J., Schultz, P.A., Jastrow, J.D., and Merckx, R. 1999. Recycling of sodium polytungstate used in soil organic matter studies. Soil Biology & Biochemistry 31:11931196.Google Scholar
38SAS Institute 2008. The SAS System for Windows. 9.2 ed.SAS Institute, Inc., Cary, NC.Google Scholar
39Richards, J.E., Bates, T.E., and Sheppard, S.C. 1995. Changes in the forms and distribution of soil phosphorus due to long-term corn production. Canadian Journal Soil Science 75:311318.Google Scholar
40Mäder, P., Fliessbach, A., Dubois, D., Gunst, L., Fried, P., and Niggli, U. 2002. Soil fertility and biodiversity in organic farming. Science 296:16941697.Google Scholar
41Green, V.S., Dao, T.H., Stone, G., Cavigelli, M.A., Baumhardt, R.L., and Devine, T.E. 2007. Bioactive phosphorus loss in simulated runoff from a phosphorus-enriched soil under two forage management systems. Soil Science 172:721732.Google Scholar
42Li, H., Shen, J., Zhang, F., Clairotte, M., Drevon, J.J., Cadre, E., and Hinsinger, P. 2007. Dynamics of phosphorus fractions in the rhizosphere of common bean (Phaseolus vulgaris L.) and durum wheat (Triticum turgidum durum L.) grown in monocropping and intercropping systems. Plant and Soil 312:139150.Google Scholar
43Oberson, A., Friesen, D.K., Tiessen, H., Morel, C., and Stahel, W. 1999. Phosphorus status and cycling in native savanna and improved pastures on an acid low-P Colombian Oxisol. Nutrient Cycling in Agroecosystems 55:7788.Google Scholar
44Carter, M.R. 2002. Soil quality for sustainable land management: Organic matter and aggregation interactions that maintain soil functions. Agronomy Journal 94:3847.Google Scholar
45Hernandez-Ramirez, G., Brouder, S.M., Smith, D.R., and Van Scoyoc, G.E. 2009. Carbon and nitrogen dynamics in an eastern corn belt soil: Nitrogen source and rotation. Soil Science Society of America Journal 73:128137.CrossRefGoogle Scholar
46Smith, R.G., Menalled, F.D., and Robertson, G.P. 2007. Temporal yield variability under conventional and alternative management systems. Agronomy Journal 99:16291634.Google Scholar
47Crews, T.E. 2005. Perennial crops and endogenous nutrient supplies. Renewable Agriculture and Food Systems 20:2537.CrossRefGoogle Scholar
48Kamh, M., Abdou, M., Chude, V., Wiesler, F., and Horst, W.J. 2002. Mobilization of phosphorus contributes to positive rotational effects of leguminous cover crops on maize grown on soils from northern Nigeria. Journal of Plant Nutrition and Soil Science 165:566572.Google Scholar
49Nuruzzaman, M., Lambers, H., Bolland, M.D.A., and Veneklaas, E.J. 2005. Phosphorus uptake by grain legumes and subsequently grown wheat at different levels of residual phosphorus fertiliser. Australian Journal of Agricultural Research 56:10411047.Google Scholar