Winter Rye Cover Crop Biomass Production, Degradation, and Nitrogen Recycling

Pantoja, José L.; Woli, Krishna P.; Sawyer, John E.; Barker, Daniel W.

doi:10.2134/agronj2015.0336

Cited by 45 publications

(48 citation statements)

References 55 publications

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“…Cereal rye shoot N loss ranged from 5 to 30 kg N ha −1 , resulting in approximately 45% loss of residue N by 86 DAP, a finding consistent with other studies (Poffenbarger et al 2015;Pantoja et al 2016). Most studies examining decomposition of cover crop surface residues have considered the effects of residue quality rather than residue quantity on net N mineralization (Reberg-Horton et al 2012;Lawson et al 2012;Wells et al 2013;Parr et al 2014;Poffenbarger et al 2015).…”

Section: Discussionsupporting

confidence: 82%

Establishing the relationship of soil nitrogen immobilization to cereal rye residues in a mulched system

et al. 2018

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Background and aims Soil nitrogen (N) immobilization from cover crop residues may help suppress weeds. We established a gradient of cereal rye shoot biomass to determine the extent that soil N can be immobilized and its effect on redroot pigweed (Amaranthus retroflexus L.). . Pigweed tissue N and biomass were reduced in the presence of cereal rye. The magnitude of pigweed N reduction was similar across all shoot application rates. Conclusions We found weak evidence for a cereal rye shoot-based N immobilization mechanism of weed suppression. Our results indicate N immobilization may be primarily due to root residues.

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Section: Discussionsupporting

confidence: 82%

Establishing the relationship of soil nitrogen immobilization to cereal rye residues in a mulched system

et al. 2018

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“…The RCC biomass C to N ratio in our study was low (15:1), which indicates there should be net mineralization of N, although the amount would be small. In a study by Pantoja et al (2016) with RCC following soybean, the RCC had a low C to N ratio (14:1) and recycled 22 kg N ha −1 (80%) by 105 d after termination.…”

Section: Resultsmentioning

confidence: 99%

“…A net N immobilization through 7 d with incubation of aboveground rye material and at the end of 20 d of rye root incubation was reported by Woli et al (2016) and Gardner and Sarrantonio (2012), while a net release of N from the decomposition of oat ( Avena sativa L.) and rye roots over a period of 112 d was reported in an incubation study by Malpassi et al (2000). A study by Pantoja et al (2016) reported that only 25% of N present in aboveground RCC biomass was released by 21 d after termination. This suggests that the use of starter N at planting would help offset N stress on corn due to the presence of decomposing RCC biomass and associated effects on inorganic‐N availability.…”

Section: Resultsmentioning

confidence: 99%

Can Management Practices Enhance Corn Productivity in a Rye Cover Crop System?

2019

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Cereal rye (Secale cereale L.) cover crops (RCC) have good potential to take up residual NO3 between grain crops and reduce loss to surface waters. However, studies in Iowa have shown a 6% corn (Zea mays L.) yield reduction in no‐till when grown following a RCC. The objective of this research was to study tillage and starter N agronomic practices that have potential to improve corn yield in a RCC system. This study was conducted at four sites from 2014–2016 with corn grown in rotation with soybean [Glycine max. (L.) Merr.]. Treatments included rye aerial broadcast into soybean before leaf drop and no RCC, tillage or no‐till, and starter N fertilizer (34 kg N ha−1) or no starter. The main fertilizer N was sidedressed. The aerial rye sowing, especially with dry fall conditions and planned RCC termination in the spring at 15–20 cm height, resulted in non‐uniform RCC stand with low biomass and N content (range 6–36 kg N ha−1). However, the profile soil NO3–N at rye termination was decreased, approximately the same amount as the RCC aboveground N content. The V6 stage corn height and V10 stage canopy sensing indexes increased with tillage and starter. Overall, corn yield was reduced with the RCC (0.2 Mg ha−1), tillage increased yield (3%), but starter N did not increase yield despite consistent increased early corn growth. If soil erosion potential is low, springtime tillage would be a practice to help improve corn early growth and yield in a RCC system. Core Ideas A cereal rye cover crop preceding corn can result in reduced grain yield. Rye cover crop did not affect corn plant population. Starter N improved early corn growth but not grain yield. Corn yield was 1.6% reduced with the rye cover crop, but tillage improved yield by 3%.

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“…Using cover crops before the summer crop resulted in a greater accumulation of N compared to that of the fallow treatment ( Table 3). Systems that do not accumulate significant quantities of N limit its supply for the following crop (Pantoja, Woli, Sawyer, & Barker, 2016). Additionally, species that favor greater N cycling and/or fixation in the offseason enable production systems that prioritize conservation concepts and minimize production costs (Koefender, Schoffel, Manfio, & Golle, 2016).…”

Section: Accumulation Of Dry Mass and Nutrients In Cover Cropsmentioning

confidence: 99%

Do cover crops improve the productivity and industrial quality of upland rice?

et al. 2020

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Global rice (Oryza sativa L.) cultivation is expected to increase, especially in upland no‐tillage systems (NTS). The difficulty in producing and maintaining straw in NTS in the Brazilian Cerrado and comparative regions worldwide can be overcome by using cover crops in irrigated areas. The potential of straw accumulation, soil cover maintenance, and nutrient cycling is considered while choosing cover crop species, because these characteristics may interfere with subsequent crop cultivation. This study was conducted to determine whether cover crops could benefit the development, productivity, and industrial quality of upland rice grains irrigated by sprinklers and cultivated in succession. The experiment was conducted in the Cerrado, with a summer rainy season and a dry winter. The treatments consisted of six cover crops (millet [Pennisetum glaucum], sunn hemp [Crotalaria juncea], pigeonpea [Cajanus cajan], millet + sunn hemp, millet + pigeonpea, and fallow) sowed in winter or spring. Compared to fallow, the cover crops cultivated in winter or spring led to increased straw production, accumulation of approximately 150% more nitrogen in straw, and possibly improved rice nutritional value because of the higher N content. Rice plants cultivated after sunn hemp developed a greater dry mass than rice cultivated after the fallow treatment. Grain yield was not influenced by the cover crops. However, sunn hemp cultivation increased the milling yield, head rice yield, and the milled rice productivity (MRP), compared to cultivation following the fallow treatment. Cultivation of sunn hemp before the upland rice crop improved MRP compared to that following the fallow treatment.

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Winter Rye Cover Crop Biomass Production, Degradation, and Nitrogen Recycling

Cited by 45 publications

References 55 publications

Establishing the relationship of soil nitrogen immobilization to cereal rye residues in a mulched system

Establishing the relationship of soil nitrogen immobilization to cereal rye residues in a mulched system

Can Management Practices Enhance Corn Productivity in a Rye Cover Crop System?

Do cover crops improve the productivity and industrial quality of upland rice?

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