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Physiological and yield response in maize in cohesive tropical soil is improved through the addition of gypsum and leguminous mulch

Published online by Cambridge University Press:  01 April 2020

E. G. Moura Open the ORCID record for E. G. Moura [Opens in a new window] ,
P. D. Hallett ,
S. J. Mooney ,
F. R. Silva ,
V. R. A. Macedo  and
A. C. F. Aguiar
E. G. Moura*
Affiliation:
State University of Maranhao, Agroecology Program, Sao Luis, Maranhao, 65054-970, Brazil
P. D. Hallett
Affiliation:
School of Biological Sciences, University of Aberdeen, Aberdeen, AB24 3UU, UK
S. J. Mooney
Affiliation:
School of Biosciences, University of Nottingham, Sutton Bonington Campus, Loughborough, Leics, LE12 5RD, UK
F. R. Silva
Affiliation:
State University of Maranhao, Agroecology Program, Sao Luis, Maranhao, 65054-970, Brazil
V. R. A. Macedo
Affiliation:
Instituto Federal de Educação, Ciência e Tecnologia do Piauí, Campus Uruçuí – Rodovia PI 247, Km 7, S/N, Portal do Cerrado, Uruçuí 64860-000, Brazil
A. C. F. Aguiar
Affiliation:
Biology Department, Federal University of Maranhao, Sao Luis, Maranhao, 65080-805, Brazil
*
Author for correspondence: E. G. Moura, E-mail: egmoura@elointernet.com.br
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Abstract

Tropical soils tend to harden during drying due to the generally low content of free-iron and organic carbon, combined with high fine sand and silt proportions. It was hypothesized that the change in soil physical condition induced by the addition of a leguminous mulch in cohesive tropical soil enriched with calcium may mitigate soil hardening through wetting and drying cycles by rain or irrigation, thereby improving the soil rootability. A leguminous mulch was added in different concentrations to a structurally fragile tropical soil enriched with calcium, which then had different irrigation intervals. The treatments were with or without mulch (10 t/ha), with or without added nitrogen (100 kg/ha at 2 intervals) and two irrigation intervals. In 2015 the irrigation intervals were either 4 or 8 days, and in 2016 they were either 6 or 9 days. Two years were used in the attempt to achieve greater differences, as for tested variables, between treatments. Maize planted in these soil treatments was measured for physiological performance, water use efficiency and yield. Mulch used on structurally fragile tropical soil enriched with calcium was found to delay increased penetration resistance from hardening by wet/dry cycles. In this context, an improved soil rootability led to an enlargement of the leaf area index, greater nitrogen uptake and increased CO2 assimilation. This had important physiological consequences due to the positive effect on increased dry matter production and maize yield. In addition, these results suggested that mulch, used with urea, can delay the water supply for 3 or 4 days due to improvements in soil rootability caused by calcium and organic matter interactions. This may be crucial to a region where small intervals without rain are increasingly common due to global climate change. Therefore, due to a greater water use efficiency, this strategy may be a profitable way to increase crop productivity in tropical conditions rather than increasing water and nutrient application alone.

Keywords

Irrigation intervalsleguminousnitrogensoil strengthwater stressZea mays L
Type
Crops and Soils Research Paper
Information
The Journal of Agricultural Science , Volume 158 , Issue 1-2 , March 2020 , pp. 57 - 64
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Copyright
Copyright © Cambridge University Press 2020

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References

Anikwe, MAN, Eze, JC and Ibudialo, AN (2016) Influence of lime and gypsum application on soil properties and yield of cassava (Manihot esculenta Crantz.) in a degraded Ultisol in Agbani, Enugu Southeastern Nigeria. Soil & Tillage Research 158, 3238.CrossRefGoogle Scholar
Aula, L, Macnack, N, Omara, P, Mullock, J and Raun, W (2016) Effect of fertilizer nitrogen (N) on soil organic carbon, total N, and soil pH in long-term continuous winter wheat (Triticum aestivum L.). Communications in Soil Science and Plant Analysis 47, 863874.10.1080/00103624.2016.1147047CrossRefGoogle Scholar
Becher, HH, Breuer, J and Klingler, B (1997) An index value for characterizing hardsetting soils by fall-cone penetration. Soil Technology 10, 4756.CrossRefGoogle Scholar
Cambardella, CA and Elliott, ET (1992) Particulate soil organic-matter changes across a grassland cultivation sequence. Soil Science Society American Journal 56, 777783.CrossRefGoogle Scholar
Carrizo, ME, Alesso, CA, Cosentino, D and Imhoff, S (2015) Aggregation agents and structural stability in soils with different texture and organic carbon contents. Scientia Agricola 72, 7582.CrossRefGoogle Scholar
Carter, MR and Gregorich, EG (2008) Soil Sampling and Methods of Analyses. New York: CRS Press.Google Scholar
Christensen, BT (2000) Organic Matter in Soil: Structure, Function and Turnover. Tjele: Dias.Google Scholar
Daniells, IG (2012) Hardsetting soils: a review. Soil Research 50, 349359.10.1071/SR11102CrossRefGoogle Scholar
Denmead, OT and Shaw, RH (1962) Availability of soil water to plants as affected by soil moisture content and meteorological conditions. Agronomy Journal 54, 385390.CrossRefGoogle Scholar
Graça, JP, Rodrigues, FA, Farias, JRB, Oliveira, MCN, Hoffmann-Campo, CB and Zingaretti, SM (2010) Physiological parameters in sugarcane cultivars submitted to water deficit. Brazilian Journal of Plant Physiology 22, 189197.10.1590/S1677-04202010000300006CrossRefGoogle Scholar
Legendre, P and Gallagher, ED (2001) Ecologically meaningful transformations for ordination of species data. Oecologia 129, 271280.10.1007/s004420100716CrossRefGoogle ScholarPubMed
Levidow, L, Pimbert, M and Vanloqueren, G (2014) Agroecological research: conforming – or transforming the dominant agro-food regime? Agroecology and Sustainable Food Systems 38, 11271155.10.1080/21683565.2014.951459CrossRefGoogle Scholar
Moore, TR and Turunen, J (2004) Carbon accumulation and storage in mineral subsoil beneath peat. Soil Science Society American Journal 68, 690696.CrossRefGoogle Scholar
Moura, EG, Serpa, SS, Santos, JGD, Costa Sobrinho, JR and Aguiar, ACF (2010) Nutrient use efficiency in alley cropping systems in the Amazonian periphery. Plant and Soil 335, 363371.CrossRefGoogle Scholar
Moura, EG, Oliveira, AK, Coutinho, CG, Pinheiro, KM and Aguiar, ACF (2012) Management of a cohesive tropical soil to enhance rootability and increase the efficiency of nitrogen and potassium use. Soil and Use Management 28, 368375.10.1111/j.1475-2743.2012.00424.xCrossRefGoogle Scholar
Moura, EG, Marques, ES, Silva, TMB, Piedade, AR and Aguiar, ACF (2014) Interactions among leguminous trees, crops and weeds in a no-till alley cropping system. International Journal of Plant Production 8, 441456.Google Scholar
Moura, EG, Macedo, VRA, Sena, VGL, Campos, LS and Aguiar, ACF (2017) Soil physical changes and maize growth in a structurally fragile tropical soil due to mulching and duration between irrigation intervals. Soil and Use Management 3, 631638.CrossRefGoogle Scholar
Moura, EG, Portela, SB, Macedo, VRA, Sena, VGL, Sousa, CCS and Aguiar, ACF (2018) Gypsum and legume residue as a strategy to improve soil conditions in sustainability of agrosystems of the humid tropics. Sustainability 10, 1006.10.3390/su10041006CrossRefGoogle Scholar
Mueller, ND, Gerber, JS, Johnston, M, Ray, DK, Ramankutty, N and Foley, JA (2012) Closing yield gaps through nutrient and water management. Nature 490, 254257.CrossRefGoogle ScholarPubMed
Mulumba, LN and Lal, R (2008) Mulching effects on selected soil physical properties. Soil & Tillage Research 98, 106111.CrossRefGoogle Scholar
R Development Core Team (2009) R: A language and environment for statistical computing. Vienna, Austria: R Foundation for Statistical Computing, http://www.R-project.org.Google Scholar
Sadras, VO and Milroy, SP (1996) Soil-water thresholds for the responses of leaf expansion and gas exchange: a review. Field Crop Research 47, 253266.CrossRefGoogle Scholar
Shepherd, MA, Harrison, R and Webb, J (2002) Managing soil organic matter-implications for structure on organic farms. Soil and Use Management 18, 284292.CrossRefGoogle Scholar
Soil Survey Staff (2014) Keys to Soil Taxonomy. Washington, DC: USDA-Natural Resources Conservation Service.Google Scholar
Sumner, ME (2009). Gypsum improves subsoil root growth. Proceedings of International symposium “Root Reseacher and Aplications, September, 2–4, BOKU, Viena, Austria, 1–4.Google Scholar
van Raij, B, Andrade, JC, Cantarella, H and Quaggio, JA (2001) Análise Química Para Avaliação da Fertilidade de Solos Tropicais. Campinas: Instituto Agronômico.Google Scholar
Whittinghill, K, Hobbie and Sarah, E (2012). Effects of pH and calcium on soil organic matter dynamics in Alaskan tundra. Biogeochemistry 111, 569581.10.1007/s10533-011-9688-6CrossRefGoogle Scholar
Wuddivira, MN and Camps-Roach, G (2007) Effects of organic matter and calcium on soil structural stability. European Journal of Soil Science 58, 722727.CrossRefGoogle Scholar
Yi, L, Shenjiao, Y, Shiqing, L, Xinping, C and Fang, C (2010) Growth and development of maize (Zea mays L.) in response to different field water management practices: resource capture and use efficiency. Agricultural and Forestry Meteorology 150, 606613.10.1016/j.agrformet.2010.02.003CrossRefGoogle Scholar