Sweet corn production and efficiency of nitrogen use in high cover crop residue

Teasdale, John R.; Abdul‐Baki, Aref A.; Park, Yong Bong

doi:10.1051/agro:2008029

Cited by 43 publications

(33 citation statements)

References 26 publications

(31 reference statements)

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“…Adequate summer rainfall (Table 3) Higher plant available N during the sweet corn season at Ridgetown than Bothwell (Table 7) provides some explanation as to why cover crops affected sweet corn yield in the 0 kg N ha (1 but not the 140 kg N ha (1 treatment at Bothwell and why there was no cover crop effect with or without N fertilizer at Ridgetown. In general, the positive effect of N fertilizer on total and marketable yield at Bothwell, and in total yield at Ridgetown was consistent with other research (Burket et al 1997;Mullins et al 1999;Griffin et al 2000;Cline and Silvernail 2002;Teasdale et al 2008). Similar to our study, Mullins et al (1999), Burket et al (1997), and Griffin et al (2000) observed variable weather during their studies, including hot dry years.…”

Section: Yield and Profit Marginssupporting

confidence: 92%

“…Similar to our study, Mullins et al (1999), Burket et al (1997), and Griffin et al (2000) observed variable weather during their studies, including hot dry years. As well, with the exception of the study by Teasdale et al (2008), which was conducted on loamy sand soil, the other studies (Burket et al 1997;Mullins et al 1999;Griffin et al 2000;Cline and Silvernail 2002) occurred predominately on silt loam soils and therefore were less sandy than the soils in our study. Similar to our study, effects of cover crops on sweet corn yield showed mixed and often contrasting results depending on site-year (Carrera et al 2004;Malik et al 2008).…”

Section: Yield and Profit Marginscontrasting

confidence: 57%

“…At Ridgetown, N treatment had no effect on sweet corn shoot biomass production at any time during the sweet corn season, likely due to high plant available N over the growing season (data not shown). Other research has also shown that fertilization does not necessarily lead to increased sweet corn biomass or plant populations (Dyck and Liebman 1994;Mullins et al 1999;Teasdale et al 2008). Similarly, others have found that neither cover crops (Teasdale et al 2008;Burgos and Talbert 1996) nor N treatment (Isse et al 1999) had an effect on sweet corn biomass.…”

Section: Yield and Profit Marginsmentioning

confidence: 95%

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Nitrogen cycling, profit margins and sweet corn yield under fall cover crop systems

et al. 2012

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, L. L. 2012. Nitrogen cycling, profit margins and sweet corn yield under fall cover crop systems. Can. J. Soil Sci. 92: 353Á365. In order to improve N best management practices in southwestern Ontario vegetable farming, the effect of cover crops on N dynamics in the fall and spring prior to sweet corn planting and during sweet corn season was assessed. The experiment was a split plot design in a fresh green pea Á cover crop Á sweet corn rotation that took place over 2 site-years at Bothwell and Ridgetown in 2006Á2007 and 2007Á2008, respectively. The main plot factor was fall cover crop type with five treatments including oat (Avena sativa L.), cereal rye (Secale cereale L.), oilseed radish (OSR; Raphanus sativus L. var. oleoferus Metzg Stokes), mixture OSR plus cereal rye (OSR&rye) and a no cover crop control. Compared with no cover crop, sweet corn profit margins were higher by $450 ha (1 for oat at Bothwell and $1300 and $760 ha (1 for OSR and OSR&rye, respectively, at Ridgetown. By comparing plant available N over the cover crop season, the cover crops tested were more effective at preventing N loss at Bothwell than at Ridgetown likely due to higher precipitation and sandier soil at Bothwell. Despite differences in site characteristics, cover crops did not result in increased plant available N compared with no-cover during the sweet corn season at either site, indicating that these cover crops will not provide an N credit to the following crop and growers should not modify N fertilizer applications based on cover crops. n te´moin, soit l'absence de culture-abri. Comparativement au traitement te´moin, la marge de profit du maı¨s sucre´a augmente´de 450 $ par hectare avec l'avoine, a`Bothwell, ainsi que de 1 300 $ et de 760 $ par hectare avec le radis et le me´lange radis/seigle, respectivement, a`Ridgetown. Quand on compare la quantite´de N a`la disposition des plantes durant la croissance de la culture-abri, on constate que les cultures teste´es pre´viennent mieux les pertes de N a`Bothwell qu'aR idgetown, sans doute a`cause de pre´cipitations plus abondantes et d'un sol plus sablonneux. En de´pit des diffe´rences observe´es au niveau des particularite´s du site, la culture-abri n'a accru la quantite´de N disponible pour les plantes a`aucun des deux endroits pendant la saison de croissance du maı¨s sucre´, comparativement au traitement te´moin, signe que les cultures teste´es n'ajoutent pas du N au sol pour la culture subse´quente et que les cultivateurs ne devraient pas modifier leurs applications d'engrais N en fonction de la culture-abri.Mots clé s: É conomique, culture de´robe´e, perte de nitrates, avoine, seigle, radis, bilan azoteẂ ith over 30 000 ha of land in production, sweet corn is the most widespread field-grown vegetable crop in Canada. With approximately 50% of the national acreage, Ontario is the largest sweet corn producing province with a farm value of $25.5 million in 2007 (Mailvaganam 2008). With such a large acreage, it is important that sweet corn production not only optimizes returns b...

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Section: Yield and Profit Marginssupporting

confidence: 92%

Section: Yield and Profit Marginscontrasting

confidence: 57%

Section: Yield and Profit Marginsmentioning

confidence: 95%

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Nitrogen cycling, profit margins and sweet corn yield under fall cover crop systems

et al. 2012

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“…Only for tomato marketable yield of 2009 and 2010 variations were clearly due to causes other than N availability: in 2009 it was conventional tomato that yielded less that potential due to a bad crop establishment; this because a 50 mm rainfall occurred during seedbed preparation impeding an adequate soil loosening which, on the contrary, could be obtained in the organic soil thanks to green manure biomass incorporated just before; in 2010 the marketable yield loss of organic tomato was due to an unsuccessful mechanical control of weed infestation and to a higher proportion of unmarketable fruits over conventional tomato (36% vs 20% of total fruit weight in ORG and LOW, respectively). A lower yield was reported in several studies where maize was grown organically (Mischler et al, 2010;Wortman et al, 2012) or fertilized by cover crops (Tonitto et al, 2006;Teasdale et al, 2008) and was often explained by the lower and variable N supply from green manures. In turn, the growth and Ndfa accumulation of green manures was affected by fall winter climate and was actually much variable.…”

Section: Discussionmentioning

confidence: 84%

“…These two crops differ much for N uptake capacity (also due to different plant spacing), total amount and timing of N need, effect of N on crop yield (also due to different requirements for marketable yield between a cereal and a vegetable). Maize is a high N demanding crop with early spring sowing and green manures may not guarantee an adequate N availability especially in early growth phases, with consequent lower growth and grain yield (Benincasa et al, , 2010Teasdale et al, 2008). Processing tomato may better use organic N sources in virtue of its lower and later N need due to its mid spring transplanting date .…”

Section: Introductionmentioning

confidence: 99%

Nine-year results on maize and processing tomato cultivation in an organic and in a conventional low input cropping system

et al. 2013

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Nine-year results on yields and apparent balances of organic matter and nitrogen (N) are reported for maize and processing tomato cultivated in a long term comparison trial between an organic and a conventional low-input system in Central Italy. In every year, above ground biomass and N accumulation of each cash crop and green manure, including weeds, and the partitioning between marketable yield and crop residues were determined. Apparent dry matter and nitrogen balances were calculated at the end of each crop cycle by taking into account the amounts of dry matter and ex-novo N supplied to the system as green manure legume Ndfa (i.e. an estimate of N derived from the atmosphere via symbiotic fixation) and fertilizers, and those removed with marketable yield. Processing tomato complied with organic cultivation better than maize. As compared to the conventional crop cultivation, organic tomato provided similar yields, used supplied N more efficiently and left lower residual N after harvest, with lower related risks of pollution. Organic maize yielded less than conventional one. The main limitation for organic maize was the low N availability during initial growth phases, due to either low N supply or low rate of N release from incorporated green manure biomass. In both organic and conventional cultivation the system sustainability could be improved by an appropriate crop rotation: wheat in fall winter likely prevented leaching loss of mineral N in both systems; green manure crops in the organic system allowed to either trap and recycle soil mineral N or supply ex novo legume Ndfa to the soil, with benefits in mitigation of N pollution and improvement in self-sufficiency of the system.

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Short‐term corn yield response associated with nitrogen dynamics from fall‐seeded cover crops under no‐till dryland conditions

Chim

Osborne

Lehman

2022

Agrosystems Geosci & Env

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The availability of in‐season N to corn (Zea mays L.) following fall‐seeded cover crops depends on seasonal patterns of nitrogen (N) transformations that are site‐ and year‐dependent and resist prediction. Our objectives were to evaluate N dynamics following different cover crops (legume, nonlegume, none) and their relationship with subsequent corn yields within an established no‐till winter wheat (Triticum aestivum L.)–cover crop/corn–soybean (Glycine max) rotation over two site‐years in the U.S. Northern Plains. Spring cover crop biomass and N uptake, in‐situ soil N mineralization following cover crop termination, and corn grain yield and N uptake were measured. Legume cover crops were associated with higher corn yields, whereas rye (Secale cereale) did not significantly decrease corn yields despite N immobilization by a large rye cover crop in one year. Legume cover crops produced the highest rates of N mineralization during periods of high N demand by corn (V6–R3) and the highest seasonal amounts of mineralized N compared with rye or no cover crops. In‐situ N mineralization measurements better predicted yields across all treatments compared with approaches using cover crop biomass and N content. In situ N mineralization rates during corn growth stages V6–R3 provided a superior prediction (r = .83) of corn yields compared with all seasonal estimates of N provided by cover crops. Lower apparent N use efficiency calculated with contributions of in‐season N mineralization indicated that less fertilizer N can be applied in the growing season following legume cover crops.

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Sweet corn production and efficiency of nitrogen use in high cover crop residue

Cited by 43 publications

References 26 publications

Nitrogen cycling, profit margins and sweet corn yield under fall cover crop systems

Nitrogen cycling, profit margins and sweet corn yield under fall cover crop systems

Nine-year results on maize and processing tomato cultivation in an organic and in a conventional low input cropping system

Short‐term corn yield response associated with nitrogen dynamics from fall‐seeded cover crops under no‐till dryland conditions

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