Rye–Corn Silage Double‐Cropping Reduces Corn Yield but Improves Environmental Impacts

Krueger, Erik S.; Ochsner, Tyson; Baker, John M.; Porter, Paul M.; Reicosky, D. C.

doi:10.2134/agronj2011.0341

Cited by 38 publications

(39 citation statements)

References 47 publications

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“…Krueger et al (2012) indicated that corn yield decrease with RCC was likely a result of the rye-corn rotation affecting corn growth rather than RCC effects on soil supply of PAN, which could have been the case in our study and was confirmed by the relatively small differences in soil profile NO 3 -N between no-RCC and RCC. Corn grain yield decreased as RCC biomass increased.…”

Section: Corn Yield and Nitrogen Response Corn Yieldsupporting

confidence: 79%

“…However, research has found differing annual crop yield responses with RCC. Corn grain and silage yield decreases have been reported with use of RCC (Raimbault et al, 1990;Kessavalou and Walters, 1997;Thelen and Leep, 2002;Singer and Kohler, 2005;McDonald et al, 2008;Kramberger et al, 2009;Salmerón et al, 2011;Krueger et al, 2012;Reese et al, 2014). A 15% corn yield increase was observed in 2 out of 3 yr in a study conducted on sandy soils in Wisconsin with no N application to the RCC and with low RCC biomass production .…”

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confidence: 99%

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Corn Nitrogen Fertilization Requirement and Corn-Soybean Productivity with a Rye Cover Crop

Pantoja

Woli

Sawyer

et al. 2015

Soil Science Society of America Journal

102

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winter rye (Secale cereale l.) cover crop (rcc) has potential to reduce no 3 -n loss from corn (Zea mays l.) and soybean [Glycine max (l.) Merr.] fields. However, rcc effects on annual crop productivity and corn optimal n fertilization requirement are unclear. the objectives were to evaluate corn and soybean yield response to rcc and corn optimal n rate. treatments were no-rcc and rcc with six fertilizer n rates (0-225 kg n ha -1 ) applied to corn in a no-till corn-soybean (cs) rotation at four iowa sites in 2009 through 2011. the rcc biomass and n uptake was low, with a maximum of 1280 kg dry matter (dM) ha -1 and 26 kg n ha -1 , respectively. in the no-n control, the rcc reduced soil profile no 3 -n by 15 kg n ha -1 only at time of rcc control before corn planting. corn canopy sensing, plant height, and plant population indicated more n stress, reduced plant stand, and slower growth with rcc. the rcc reduced corn grain yield by 6% at the economic optimum n rate (eonr). the eonr was the same with no-rcc and rcc, but plant n uptake efficiency (Pue) was reduced at low n rates with rcc, but not above the eonr. soybean yield was not affected by rcc. results indicate n fertilization rate should be the same with or without rcc. improvement in rcc systems and management could make rcc a more viable practice within notill corn and soybean production.Abbreviations: CS, corn-soybean; DM, dry matter; EONR, economic optimum nitrogen rate; NDVI, normalized difference vegetative index; NUE, nitrogen use efficiency; PAN, plant available nitrogen; PUE, plant nitrogen uptake efficiency; RCC, rye cover crop; SOM, soil organic matter; YEONR, yield at economic optimum nitrogen rate. E nvironmental concerns related to crop N fertilization is an ongoing issue (USEPA, 2007), including reducing N in surface waters related to hypoxia in coastal surface waters Kladivko et al., 2014). Nitrogen application rate to corn is an important factor in regard to cropping system profitability and NO 3 loss. Applying only the optimal N rate will not stop NO 3 loss, nor necessarily achieve the drinking water standard (Lawlor et al., 2007). Successful development of agricultural systems that benefit water quality have to be more inclusive of several agricultural practices, rather than only N rate or timing (Hatfield et al., 2009). Therefore, additional in-field practices are needed to reduce NO 3 losses (Sainju and Singh, 2008).Nitrate losses in tile drainage water from corn production systems can range from 7 to 68 kg N ha -1 yr -1 (Lawlor et al., 2007), and with most values ranging from 29 to 56 kg N ha -1 yr -1 (Sawyer and Randall, 2008). Cover crops have shown potential for uptake of residual N from fertilizers or inorganic N released from degrading soil organic matter (SOM) in the period between annual crops (Strock et al., 2004;Tonitto et al.,

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Section: Corn Yield and Nitrogen Response Corn Yieldsupporting

confidence: 79%

mentioning

confidence: 99%

Corn Nitrogen Fertilization Requirement and Corn-Soybean Productivity with a Rye Cover Crop

Pantoja

Woli

Sawyer

et al. 2015

Soil Science Society of America Journal

102

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“…Results confirmed that, when planted after corn silage harvest, a rye cover crop can provide environmental benefits (Krueger et al 2010;Krueger et al 2011;Krueger et al 2012) without impacting subsequent corn yield even in a cold climate (Krueger et al 2011). Rye/corn silage cropping systems prevented soil NO 3 -N accumulation and reduced soil solution NO 3 -N concentration compared with corn silage alone, while also increasing ground cover and soil organic C (SOC) relative to corn silage without a cover crop (Krueger et al 2010;Krueger et al 2011;Krueger et al 2012). However, when rye was allowed to grow until it could be harvested for forage (i.e., forage double-cropping), significant reductions in subsequent corn silage yield occurred, primarily resulting from soil moisture and NO 3 -N depletion that increased with greater rye growth.…”

mentioning

confidence: 67%

“…With its short growing season, corn silage provides little vegetative cover much of the year (Krueger et al 2012), which leaves the soil prone to erosion by wind and water Abstract: Increased corn (Zea mays L.) silage and manure production accompanying the proliferation of large dairies has prompted concern regarding their environmental impacts. The objectives of this on-farm, field-scale study were (1) to quantify environmental impacts, e.g., soil chemical properties and offsite nutrient transport, of corn silage production with dairy manure application on artificially drained soils and (2) to assess the environmental benefits of and agronomic constraints on the adoption of winter rye (Secale cereale L.) cover cropping by a large dairy in west central Minnesota.…”

mentioning

confidence: 99%

“…Winter rye can scavenge excess soil NO 3 -N (Jewett and Thelen 2007) and reduce NO 3 -N leaching (Kaspar 2007;Strock et al 2004), while rye biomass returned to the soil can maintain or increase soil carbon (C) (Kaspar et al 2006;Kuo et al 1997). Rye can increase fall and spring ground cover compared with winter fallow (Krueger et al 2012), which can reduce soil erosion (Kaspar et al 2001) and off-site nutrient transport. Still, farmers are hesitant to plant cover crops because of associated costs, lack of information, and time constraints arising from the limited growing season in the Upper Midwest, and as a result, cover crop adoption rates are low in the region, with only about 18% of farmers having used cover crops (Singer et al 2007).…”

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confidence: 99%

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On-farm environmental assessment of corn silage production systems receiving liquid dairy manure

Krueger¹,

Baker²,

Ochsner³

et al. 2013

Journal of Soil and Water Conservation

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The trend toward large-scale dairy farming in the United States has come with an increased reliance on corn (Zea mays L.) silage and a geographic consolidation of manure production; cover cropping with winter rye (Secale cereale L.) is one means of minimizing negative environmental impacts of these practices.Environmental concerns posed by corn silage cropping systems and high-rate manure application are well recognized. With its short growing season, corn silage provides little vegetative cover much of the year (Krueger et al. 2012), which leaves the soil prone to erosion by wind and water Abstract: Increased corn (Zea mays L.) silage and manure production accompanying the proliferation of large dairies has prompted concern regarding their environmental impacts. The objectives of this on-farm, field-scale study were (1) to quantify environmental impacts, e.g., soil chemical properties and offsite nutrient transport, of corn silage production with dairy manure application on artificially drained soils and (2) to assess the environmental benefits of and agronomic constraints on the adoption of winter rye (Secale cereale L.) cover cropping by a large dairy in west central Minnesota. From 2007 to 2009, corn for silage was grown on two adjacent 65 ha (160 ac) fields, with rye planted after corn on one field in 2007. Liquid manure was fall applied annually at average total nitrogen (N) and phosphorus (P) rates of 410 and 98 kg ha -1 (365 and 87 lb ac -1 ), respectively. Soil nitrate nitrogen (NO 3 -N) and Olsen P accumulation did not occur with the studied cropping systems, but average annual NO 3 -N and dissolved reactive P (DRP) subsurface drainage loads were 52 and 0.8 kg ha -1 y -1 (46 and 0.7 lb ac -1 yr -1 ), respectively. Soil organic carbon (C) concentration was maintained on the field without rye and increased 15% to a depth of 15 cm (6 in) on the field with rye, but C additions with manure likely contributed to the increase. Rye reduced spring soil NO 3 -N by 46% and increased ground cover an average of fourfold compared with winter fallow. Subsurface drainage NO 3 -N concentration was reduced from 53 mg L -1 (53 ppm) without rye to 39 mg L -1 (39 ppm) with rye, but rye had no impact on DRP concentration. Rye aboveground dry matter yield was 2 Mg ha -1 (0.9 tn ac -1 ). Corn dry matter yield was 16%, or 2.7 Mg ha -1 (1.2 tn ac -1 ), lower after rye than after winter fallow. This reduced yield and the persistence of high NO 3 -N and DRP concentrations in subsurface drainage with rye indicate alternative conservation practices are warranted at this site. In general, cover cropping with winter rye provided environmental benefits over corn silage alone but also increased economic risks.

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Winter annual management to increase nutrient recovery and forage production on dairies

Binder

Karsten

Beegle

et al. 2021

Agrosystems Geosci & Env

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Management of manure and cereal rye (Secale cereale L.) has implications for crop production and nutrient cycling. This 1-yr, full-factorial experiment conducted in Pennsylvania quantified the effects of three management factors-(a) rye management (RyeM; early-terminated cover crop [CC] vs. double crop harvested a week later [DC]), (b) manure application method (ManM; unincorporated broadcast manure [BM] vs. shallow disk injected manure [IM]), and (c) fall field operation prioritization (priority; manure priority [MP] manure application in late September with rye planting in mid-October vs. rye priority [RP], rye planting in late September withmanure application in early November)-on rye biomass, nutrient recovery, and forage yield and the effect of ManM and priority on DC forage nutritive value in a rye-corn (Zea mays L.) cropping sequence. This experiment was intended to be a repeated 2-yr study, but due to MP treatment rye crop failure in the second year, the resulting 1-yr dataset was analyzed to assess priority effects. Prioritizing rye planting in the fall with DC increased total forage production and apparent N recovery (ANR) when manure was broadcast. These results highlight the value of prioritizing fall rye planting in DC systems to increase rye spring biomass and nutrient recovery when manure is broadcast. More experiments should be conducted on fall field operation timing to develop reliable recommendations.

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Rye–Corn Silage Double‐Cropping Reduces Corn Yield but Improves Environmental Impacts

Cited by 38 publications

References 47 publications

Corn Nitrogen Fertilization Requirement and Corn-Soybean Productivity with a Rye Cover Crop

Corn Nitrogen Fertilization Requirement and Corn-Soybean Productivity with a Rye Cover Crop

On-farm environmental assessment of corn silage production systems receiving liquid dairy manure

Winter annual management to increase nutrient recovery and forage production on dairies

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