Does the timing of short-term biowaste compost application affect crop growth and potential nitrate leaching? The case studies of processing tomato and cauliflower under field conditions

Authors

  • Michela Farneselli Department of Agricultural, Food and Environmental Sciences, University of Perugia, Perugia
  • Euro Pannacci Department of Agricultural, Food and Environmental Sciences, University of Perugia, Perugia
  • Francesco Tei Department of Agricultural, Food and Environmental Sciences, University of Perugia, Perugia

DOI:

https://doi.org/10.4081/ija.2022.2045

Keywords:

Nitrogen fertilisation, sustainable agriculture, vegetables, Mediterranean environment, soil organic matter, Solanum lycopersicum L, Brassica oleracea var. botrytis L.

Abstract

The feasibility of municipal solid waste compost (MSWC) as a substitute for mineral nitrogen (N) fertiliser was tested for a spring-summer (i.e., processing tomato) and an autumn-winter (i.e., cauliflower) vegetable crop grown in Mediterranean open field conditions. Two different doses (10 and 20 t dm C ha–1) and two distribution timings for each dose (i.e., early application at about nine months before processing tomato transplanting and five months before cauliflower transplanting: C10_early and C20_early; late application at about one month before processing tomato and cauliflower transplanting: C10_late and C20_late) were compared in a two-year field experiment. An unfertilised control and a 100% mineral N fertilisation (MIN, 200 kg N ha–1 for processing tomato and 150 kg N ha–1 for cauliflower) were added to the experiment. The application of MSWC significantly reduced the aboveground DM accumulation compared to the MIN in both crops, and it was inadequate to ensure a high yield for spring-summer and autumn-winter vegetables. However, the timing of compost application seems to play an essential role in reducing the reduction of crop growth due to compost application. In both tomato and cauliflower, when the MSWC was applied a few months earlier than the transplanting (i.e., in the previous summer in tomato and the previous spring in cauliflower), the DM and yield reduction was less apparent than in soil where compost was applied immediately before transplanting. Despite the lowest N-uptake associated with the MSWC application, the N-NO3 concentration in the soil solution was reduced by MSWC. In addition to the amendment effect, compost use may positively impact lowering N leaching risks in the groundwater. Combining the use of MSWC applied early before the crop season with mineral N fertiliser, it is possible to gain high yield, increase soil organic carbon and reduce groundwater contamination risk both in spring-summer and autumn-winter vegetable crops.

Highlights
- Biowaste compost decreased the aboveground biomass accumulation and yield in processing tomato and cauliflower.
- Biowaste compost alone did not meet the N requirement in processing tomato and cauliflower.
- Biowaste compost distribution in the summer before the processing tomato growing season alleviated its depressive effect in reducing DM and yield.
- Biowaste compost distribution in the spring before the cauliflower growing season alleviated its depressive effect in reducing DM and yield.
- Biowaste compost decreased the N-NO3 concentration in soil solution compared to mineral fertilisation with a positive effect in reducing N leaching risks in the groundwater.

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References

Allen RG, Pereira LS, Raes D, Smith M, 1998. Crop evapotranspiration - Guidelines for computing crop water requirements - FAO Irrigation and drainage paper 56. Food and Agriculture Organization, Rome, Italy.

Antoniadis V, 2013. Mineralization of organic-amendment-derived nitrogen in two Mediterranean soils with different organic matter contents. Commun. Soil Sci. Plant Anal. 44:2788-95,

Bruulsema T, 2018. Managing nutrients to mitigate soil pollution. Environ. Pollut. 243:1602-5.

Brunetti G, Traversa A, De Mastro F, Cocozza C, 2019. Short-term effects of synergistic inorganic and organic fertilization on soil properties and yield and quality of plum tomato. Sci. Hortic. 252:342-7.

Cameira MR, Mota M, 2017. Nitrogen related diffuse pollution from horticulture production - mitigation practices and assessment strategies. Horticulturae 3:25.

Chaparro J, Badri D, Vivanco J, 2014. Rhizosphere microbiome assemblage is affected by plant development. ISME J. 8:790-803.

De Rosa D, Basso B, Rowlings DW, Scheer C, Biala J, Grace PR, 2017. Can Organic Amendments Support Sustainable Vegetable Production? Agron. J. 109:1856-69.

Diacono M and Montemurro F, 2010. Long-term effects of organic amendments on soil fertility. A review. Agron. Sustain. Dev. 30:401-22.

EC (European Commission), 2015. Closing the Loop-An. EU Action Plan for the Circular Economy; COM (2015) 614 Final; European Commission: Brussels, Belgium.

EC (European Commission), 2018. A Sustainable Bioeconomy for Europe: Strengthening the Connection between Economy, Society and the Environment. Updated Bioeconomy Strategy; Directorate-General for Research and Innovation Unit F-Bioeconomy: Brussels, Belgium.

EC (European Commission), 2020. Database. Available from: https://ec.europa.eu/eurostat/data/database Accessed: 20 September 2021.

European Compost Network, 2010. Sustainable compost application in agriculture. ECN Info Paper, 02/2010.

Farneselli M, Benincasa P, Tosti G, Simonne E, Guiducci M, Tei F, 2015. High fertigation frequency improves nitrogen uptake and crop performance in processing tomato grown with high nitrogen and water supply, Agric. Water Manage. 154:52-8.

Farneselli M, Tosti G, Onofri A, Benincasa P, Guiducci M, Pannacci E, Tei F, 2018. Effects of N sources and management strategies on crop growth, yield, and potential N leaching in processing tomato. Eur. J. Agron. 98:46-54.

Farneselli M, Benincasa P, Tosti G, Guiducci M, Tei F, 2020. Combining green manuring and fertigation maximizes tomato crop yield and minimizes nitrogen losses. Agronomy 10:977.

Gabriel JL, Munoz-Carpena R, Quemada M, 2012. The role of cover crops in irrigated systems: water balance, nitrate leaching and soil mineral nitrogen accumulation. Agric. Ecosyst. Environ. 155:50-61.

Garcia C, Hernandez T, Coll MD, Ondoño S, 2017. Organic amendments for soil restoration in arid and semiarid areas: a review. AIMS Environ. Sci. 4:640-76.

Giannakis GV, Kourgialas NN, Paranychianakis NV, Nikolaidis NP, Kalogerakis N, 2014. Effects of municipal solid waste compost on soil properties and vegetables growth. Compost Sci. Util. 22:116-31.

Hargreaves JC, Adl MS, Warman PR, 2008. A review of the use of composted municipal solid waste in agriculture, Agr. Ecosyst. Environ 123:1-14.

Hernández T, Chocano C, Moreno JL, García C, 2014. Towards a more sustainable fertilization: Combined use of compost and inorganic fertilization for tomato cultivation. Agr. Ecosyst. Environ. 196:178-84.

Horrocks A, Curtin D, Tregurtha C, Meenken E, 2016. Municipal compost as a nutrient source for organic crop production in New Zealand. Agronomy 6:35.

Hothorn T, Bretz F, Westfall P, 2008. Simultaneous inference in general parametric models. Biom. J. 50:346-63.

Latini A, Giagnacovo G, Campiotti CA, Bibbiani C, Mariani S. 2021. A narrative review of the facts and perspectives on agricultural fertilization in Europe, with a Focus on Italy. Horticulturae. 7:158.

Martínez-Blanco J, Muñoz P, Antón A, Rieradevall J, 2011. Assessment of tomato Mediterranean production in open-field and standard multi-tunnel greenhouse, with compost or mineral fertilizers, from an agricultural and environmental standpoint. J. Clean. Prod. 19:985-97.

Maucieri C, Barco A, Borin M, 2019. Compost as a substitute for mineral N fertilization? Effects on crops, soil and N leaching. Agronomy 9:193.

Moretti B, Bertora C, Grignani C, Lerda C, Celi L, Sacco D, 2019. Conversion from mineral fertilization to MSW compost use: Nitrogen fertilizer value in continuous maize and test on crop rotation. Sci. Tot. Environ. 705:135308.

Morra L, Bilotto M, Baldantoni D, Alfani A, Baiano S, 2021. A seven-year experiment in a vegetable crops sequence: effects of replacing mineral fertilizers with biowaste compost on crop productivity, soil organic carbon and nitrates concentrations. Sci. Hortic. 290:110534.

Morra L, Pizzolongo G, Baiano S, Pentangelo A, 2013. Comparison of olive pomace and biowaste composts in a vegetable cropping systems. Ital. J. Agron. 4:206-16.

Nicoletto C, Santagata S, Sambo P, 2013. Effects of compost application on qualitative traits in cabbage. Acta Hortic. 1005:389-95.

R Core Team, 2018. R: A Language and Environment for Statistical Computing; R Foundation for Statistical Computing: Vienna, Austria. Available from: https://www.R.-project.org/ Accessed: 15 October 2020.

Sambo P, Nicoletto C, 2017. Fertilizers: criteria of choice for vegetable crops. In: Tei F, Nicola S, Benincasa P (Eds.), Advances in research on fertilization management of vegetable crops. Advances in Olericulture. Springer, Cham.

Santos A, Fangueiro D, Moral R, Bernal MP, 2018. Composts produced from pig slurry solids: nutrient efficiency and N-leaching risks in amended soils. Front. Sustain. Food Syst. 2:8.

Shabani H, Peyvast GA, Olfati JA, Kharrazi PR, 2011. Effect of municipal solid waste compost on yield and quality of egg-plant. Comun. Sci. 2:85-90.

Sharma B, Vaish B. Monika, Singh UK, Singh P, Singh RP, 2019. Recycling of organic wastes in agriculture: an environmental perspective. Int. J. Environ. Res. 13:409-29.

Tei F, De Neve S, de Haan J, Lakkenborg Kristensen H, 2020. Nitrogen management of vegetable crops. Agr. Water Manag. 240:106316.

Tempesta M, Gianquinto G, Hauser M, Tagliavini M, 2019. Optimization of nitrogen nutrition of cauliflower intercropped with clover and in rotation with lettuce. Sci. Hortic. 246:734-40.

Thompson RB, Tremblay N, Fink M, Gallardo M, Padilla FM, 2017. Tools and strategies for sustainable nitrogen fertilisation of vegetable crops. In: Tei F, Nicola S, Benincasa P (Eds.), Advances in research on fertilization management of vegetable crops. Advances in Olericulture series. Springer, Cham, Switzerland, 462:11-63.

Quiros R, Villalba G, Munoz P, Font X, Gabarrell X, 2014. Environmental and agronomical assessment of three fertilization treatments applied in horticultural open field crops. J Clean Prod 67:147-58.

Weber J, Kocowicz A, Bekier J, Jamroz E. Tyszka R, Debicka M, Parylak D, Kordas L, 2014. The effect of a sandy soil amendment with municipal solid waste (MSW) compost on nitrogen uptake efficiency by plants. Eur. J. Agron. 54:54-60.

Willekens K, Vandecasteele B, De Neve S, 2014. Limited short-term effect of compost and reduced tillage on N dynamics in a vegetable cropping system. Sci. Hortic. 178:79-86.

Zaccardelli M., Pane C., Di Mola I., Ronga D., Mori M. 2021. Municipal organic waste compost replaces mineral fertilization in the horticultural cropping systems, reducing the pollution risk. Ital. J. Agron. 16:1756.

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Published

29-06-2022

How to Cite

Farneselli, M., Pannacci, E., & Tei, F. (2022). Does the timing of short-term biowaste compost application affect crop growth and potential nitrate leaching? The case studies of processing tomato and cauliflower under field conditions. Italian Journal of Agronomy, 17(2). https://doi.org/10.4081/ija.2022.2045

Issue

Vol. 17 No. 2 (2022)

Section

Original Articles

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