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Impact Of Previous Cover Crops And Corn Stover Removal On Soil Organic Carbon Aggregate Stability And Squash Yield
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Book Synopsis Impact of Previous Cover Crops and Corn Stover Removal on Soil Organic Carbon, Aggregate Stability and Squash Yield by : Lance Ouellette
Download or read book Impact of Previous Cover Crops and Corn Stover Removal on Soil Organic Carbon, Aggregate Stability and Squash Yield written by Lance Ouellette and published by . This book was released on 2015 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Precision Planting of Cover Crop Mixtures Influence on Soil and Corn Production by : Justin M. Berberich
Download or read book Precision Planting of Cover Crop Mixtures Influence on Soil and Corn Production written by Justin M. Berberich and published by . This book was released on 2023 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: Growing winter cereal cover crops (WCCCs) has been identified as an effective in-field practice to reduce nitrate-nitrogen (N) and total phosphorus (P) losses to Upper Mississippi River Basin, USA. In this region, however, growers are reluctant to plant WCCCs prior to corn (Zea mays L.) due to soil N immobilization and corn establishment issues. Two strategies to minimize these issues are (i) incorporating legumes and brassicas into WCCCs as mixtures and (ii) precision planting of cover crops. The objective of chapter 1 was to (i) evaluate the effect of cover crop mixtures vs a no-cover crop control on soil health indicators and (ii) assess the impact of precision planting of cover crops on soil nutrient availability, soil nutrient stratification, soil permanganate oxidizable carbon (POXC) and soil organic carbon (SOC) stocks "on" and "off" the corn row over three depths (0-5, 5-20, and 20-90 cm). Treatments were (i) a no-cover crop control (NCC); (ii) no cover on corn row, hairy vetch (V) on middle row, and winter cereal rye (WCR) on the outside row of corn (NOVR); and (iii) oats (Avena sativa) and radishes (Raphanus sativus) on the corn row, V on the middle row, and WCR on the outside row (ORVR). Our results indicated NCC had lower SOC stocks than the NOVR and ORVR only at 0-5 cm depth. Soil POXC was more sensitive to cover crop management than SOC, and POXC concentrations were higher in ORVR at 5-20 cm than the NCC control. At 0-5 cm depth, cover cropping increased Bray-1 soil test P (STP). Soil test P declined over depth reflecting its immobility in the soil. Mehlich-3 soil test K (STK) was higher in cover crop treatments than the no-cover crop control at 0-5 cm depth. Soil test K was higher on corn row indicating that the oats and radish mix and corn residue decomposition releases K detectable in soil as Mehlich-3 K. Soil test sulfur was similar among treatments but higher at 20-90 cm depth reflecting S leaching and/or potential anion exchange capacity at depth that can lead to subsoil sulfate-S accumulation. These results indicate cover cropping in the fragipan belt / Alfisols of the Upper Mississippi River Basin can benefit soil after six years, but soil C benefits are limited to surface soil depths. In Chapter 2 the objectives were to (i) evaluate the biomass, nutrient concentration, and uptake of precision planted cover crop mixtures; (ii) assess whether precision planted cover crops influence corn stand density, grain yield, yield components, and nutrient balances; identify the best economically viable precision planted mixture prior to corn. Treatments were (i) a no-cover crop control (NCC); (ii) no cover on corn row, hairy vetch (V) on middle row, and winter cereal rye (WCR) + annual rye (AR) on the outside row of corn (RVSKIP); and (iii) no cover on corn row, clover (C) on the middle row, and WCR + AR on the outside row (RCSKIP). Results indicated that RVSKIP was always high yielding, with high N uptake, and low C:N ratio (25) suggesting it could release N throughout the corn growing season without immobilizing N. Cover crops influenced corn population only in one site-yr but that did not result in lower corn grain yield reflecting corn potential for filling the plant gap by creating larger ears with heavier grain (TKW). Similar corn grain in all cover crop treatments was mainly due to adding optimum N as fertilizer. We concluded that overall, cover cropping could benefit soil over a six-year period but to optimize their benefit to corn, adjustments to N should be made. Therefore, future research should focus on revisiting corn N requirement especially in cover crop mixtures with high percentage (>50%) of legumes in the mixture to determine the fertilizer value of the cover crops.
Book Synopsis The Effect of Cover Crop on Soil Carbon and Soil Water Retention in Topographically Diverse Terrain by : Jordan Beehler
Download or read book The Effect of Cover Crop on Soil Carbon and Soil Water Retention in Topographically Diverse Terrain written by Jordan Beehler and published by . This book was released on 2016 with total page 56 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Cover Crop and Soil Amendment Effects on Carbon Sequestration in a Silage Corn-soybean Cropping System by : Bradley Eric Fronning
Download or read book Cover Crop and Soil Amendment Effects on Carbon Sequestration in a Silage Corn-soybean Cropping System written by Bradley Eric Fronning and published by . This book was released on 2008 with total page 222 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Impact of Cover Crops and Crop Residue Removal on Soil Quality, N Dynamics, and Processing Tomato (Solanum Lycopersicum L.) Yield and Quality by : Inderjot Chahal
Download or read book Impact of Cover Crops and Crop Residue Removal on Soil Quality, N Dynamics, and Processing Tomato (Solanum Lycopersicum L.) Yield and Quality written by Inderjot Chahal and published by . This book was released on 2019 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: Crop residue removal negatively impacts the soil physical, chemical, and biological properties. Therefore, inclusion of cover crops (CC) in the cropping systems offers an opportunity for maintaining agroecosystem functionality and counterbalancing the negative effects of crop residue removal on soil quality. Despite the multifunctional role of CC to agroecosystems, the benefits to soil quality have not been well investigated. Therefore, a medium-term experiment, established in 2007 and repeated at an adjacent site in 2008, at University of Guelph, Ridgetown Campus was used to evaluate effects of CC (6-yr) and crop residue removal (3-yr) on soil quality (chemical, physical, and biological properties), nutrient cycling, and subsequent tomato (Solanum lycopersicum L.)-winter wheat (Triticum aestivum L.) yields in a horticultural system in 2015 and 2016. This study is the first evaluation of comparisons between soil quality tests in a CC-based horticultural system in a temperate climate. Overall, our results indicated the positive influences of CC on soil quality where CCs had greater soil quality scores using comprehensive assessment of soil health (CASH), weighted soil quality test (WSQI), and Haney soil health test (HSHT) than the no CC control (no-CC). Among the three tested soil quality tests (CASH, HSHT, and WSQI), we recommend the WSQI as a more suitable and practical method for soil quality evaluation. An increase in the soil organic C (SOC) concentration with CC compared with no-CC indicates the potential of CCs to build stable pools of soil C. Cover crop induced temporal effects on labile pools of C and N were detected in our production system indicating the potential role of CC on nutrient cycling and microbial activity. Increases (15 to 28%) in tomato yields with CC than without CC further confirms the suitability of the tested CCs for increasing crop productivity in otherwise similar cropping systems. Study results indicate the long-term implications of CC on increasing soil and crop productivity.
Book Synopsis Soil Aggregate Stability by : Edgar Allan C. Po
Download or read book Soil Aggregate Stability written by Edgar Allan C. Po and published by . This book was released on 2007 with total page 254 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Effect of Cover Crops on Nutrient Dynamics and Soil Properties in Corn-soybean Rotation in Southern Illinois by : Gurbir Singh
Download or read book Effect of Cover Crops on Nutrient Dynamics and Soil Properties in Corn-soybean Rotation in Southern Illinois written by Gurbir Singh and published by . This book was released on 2018 with total page 490 pages. Available in PDF, EPUB and Kindle. Book excerpt: Corn (Zea mays L.) and soybean ( Glycine max L.) production in the Midwest US can result in significant nutrient leaching to groundwater and surface waters, which contributes to eutrophication and hypoxia in the Gulf of Mexico. A promising strategy to control nutrient leaching and sediment runoff loss during winter fallow period is the use of cover crops (CCs). In southern Illinois, CCs are not widely adopted by farmers due to economic constraints and the lack of scientific data that supports benefits of incorporating CCs into the corn-soybean rotation. This doctoral dissertation addresses the critical question of the feasibility of the use of CCs in southern Illinois and is divided into three overarching research studies with different objectives divided into six research chapters. Research study 1 was a field experiment conducted from 2013 to 2017 to examine the effect of CCs (CC vs noCC) under two tillage systems [(no-tillage (NT) and conventional tillage (CT)] on aboveground plant attributes [dry matter yield, C:N ratio and nitrogen uptake (N uptake)], crop yields, available soil N content and N leaching in the vadose zone. The experimental layout was a randomized design with three rotations including corn-noCC-soybean-noCC [CncSnc], corn-cereal rye (Secale cereale L.) -soybean-hairy vetch (Vicia villosa R.) [CcrShv], and corn-cereal rye-soybean-oats+radish (Avena sativa L. + Raphanus sativus L.) [CcrSor] and two tillage systems. Soil samples collected after corn or soybean harvest and CC termination were analyzed for standard soil fertility parameters. Pan lysimeters installed below the 'A' horizon with depth varying from 22 to 30 cm were used for measuring soil solution nutrient concentration on weekly or biweekly basis depending on the precipitation. In NT system, the corn yield was 14% greater with CcrShv compared to CncSnc, whereas no significant difference existed in corn yield due to CC treatments within CT. Both CC treatments under NT reduced soybean yield by 24 to 27% compared to noCC. The rotations CcrShv and CcrSor with hairy vetch and oats+radish as preceding CCs resulted in 89% (37.73 vs 19.96 kg ha-1) and 68% (33.46 vs 19.96 kg ha-1) more nitrate-N (NO 3-N) leaching than the CncSnc during cash crop season 2015. During the CC season in spring 2016, cereal rye CC in CcrShv and CcrSor reduced the NO 3-N leaching by 84% (0.68 kg ha-1) and 78% (0.63 kg ha-1) compared to the CncSnc, respectively, under the CT system. Overall, our results indicated that the CT system had greater N leaching losses compared to NT system due to higher N availability in the tilled soil profile. The goal of the second research study was to understand the mechanisms of N cycling by CCs. We applied 15N labeled urea fertilizer (9.2% atom) to corn that followed hairy vetch and noCC in May 2017 to evaluate the contribution of fertilizer and soil organic matter to N leaching and quantify the 15N content of surface runoff after storm events. During the 2017 corn season, repeated soil samples were collected and analyzed for 15N fertilizer recovery in soil at three depths. 15N recovery was higher in the corn that had hairy vetch as the preceding CC than the corn that had noCC by 13.13 and 3.68 kg ha-1 on soil sampling events of 7 and 21 days after planting of corn, respectively, at the depth 15-30 cm. Overall, the cumulative loss of 15NO 3-N during corn season 2017 was
Book Synopsis Using Cover Crop Mixtures to Reduce Nitrate Leaching and Supply Nitrogen to Corn by : Charles White
Download or read book Using Cover Crop Mixtures to Reduce Nitrate Leaching and Supply Nitrogen to Corn written by Charles White and published by . This book was released on 2016 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: Agriculture faces two great sustainability challenges: the ability to provide nutrition for a growing world population and the ability to increase ecosystem services that maintain clean air, clean water, and other benefits to humanity. Planting cover crops is one management practice that can contribute towards realizing the goal of increasing ecosystem services. However, to provide multiple ecosystem services and to manage tradeoffs between services, cover crops will need to be intensively managed. This dissertation develops models and tools that can support the adaptive management of cover crops to reduce nitrate (NO3-) leaching and supply nitrogen (N) to a subsequent corn crop through N mineralized from decomposing residues. Models were developed from a wide range of cover crop experiments carried out over 14 site years that included 39 different treatments of cover crop mixtures and monocultures composed from 18 different species of grasses, brassicas, and legumes. A model for potential NO3- leaching under cover crop mixtures indicated that increasing total non-legume biomass N content (sum of fall and spring N contents) of a cover crop reduced leaching at a rate of -0.91 kg NO3--N kg-1 biomass N, up to a threshold of 51 kg N ha-1 total non-legume biomass N, above which increasing non-legume biomass N had no further effect. In a model for relative corn yield following cover crop mixtures, relative yield was negatively related to fall and spring cover crop biomass carbon to nitrogen (C:N) ratios and positively related to soil carbon (C) concentration. In another model, the response of unfertilized corn yields to a previous cover crop, relative to fallow conditions, increased with cover crop biomass N content and a decreasing biomass C:N ratio, with regression models that were different for winterkilled and winterhardy cover crops due to differences between the cover crop types in the length of decomposition and the synchrony between decomposition and corn N demand. For these models to be applicable in an adaptive management process, farmers need to be able to rapidly and inexpensively measure cover crop biomass N content. A handheld NDVI meter was able to accurately predict biomass N content in fall and spring for a wide range of cover crop types. Coupling between C and N cycles also needs to be considered in relation to predicting N mineralization from decomposing cover crops and others forms of organic matter. In models that represent soil organic C saturation, regulation of the C humification efficiency by C saturation level affected a coupled N mineralization model in a way that depended on the model structure used. Under some model structures, N mineralization increases as the C saturation level increases, which could affect the extent to which cover crop residues supply N to subsequent crops. Collectively, these models provide a foundation that can support the adaptive management of cover crops to provide N-related ecosystem services.
Book Synopsis Long-term Cropping Systems Effects on Soil Aggregate Stability, Corn Grain Yields, and Yield Stability by : Kulbhushan K. Grover
Download or read book Long-term Cropping Systems Effects on Soil Aggregate Stability, Corn Grain Yields, and Yield Stability written by Kulbhushan K. Grover and published by . This book was released on 2008 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Managing Cover Crops Profitably (3rd Ed. ) by : Andy Clark
Download or read book Managing Cover Crops Profitably (3rd Ed. ) written by Andy Clark and published by DIANE Publishing. This book was released on 2008-07 with total page 248 pages. Available in PDF, EPUB and Kindle. Book excerpt: Cover crops slow erosion, improve soil, smother weeds, enhance nutrient and moisture availability, help control many pests and bring a host of other benefits to your farm. At the same time, they can reduce costs, increase profits and even create new sources of income. You¿ll reap dividends on your cover crop investments for years, since their benefits accumulate over the long term. This book will help you find which ones are right for you. Captures farmer and other research results from the past ten years. The authors verified the info. from the 2nd ed., added new results and updated farmer profiles and research data, and added 2 chap. Includes maps and charts, detailed narratives about individual cover crop species, and chap. about aspects of cover cropping.
Book Synopsis Winter Cover Cropping in Processing Tomato Production by : Lydia Jean Stivers
Download or read book Winter Cover Cropping in Processing Tomato Production written by Lydia Jean Stivers and published by . This book was released on 1989 with total page 164 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis Winter Cereal Cover Crops and Nitrogen Management Practices for Increasing Farm Profit and Minimizing Nitrogen Losses in Corn-soybean Agroecosystems by : Oladapo Adeyemi
Download or read book Winter Cereal Cover Crops and Nitrogen Management Practices for Increasing Farm Profit and Minimizing Nitrogen Losses in Corn-soybean Agroecosystems written by Oladapo Adeyemi and published by . This book was released on 2023 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: Winter cereal cover crops (WCCCs) could provide extra profit by being harvested as forage or for biofuel purposes, could benefit soil, and the following cash crops, and are considered an effective practice in reducing the nitrate-N (NO3-N) leaching especially in corn (Zea mays L.) and soybean (Glycine max L.) fields. The extend at which WCCCs and their residue management (e.g. harvesting vs. terminating at different times) improve farm profit, influence the following cash crop, especially corn is less studied. Also, literature is scant on the residue management effects on NO3-N leaching potential and its tradeoff with soil nitrous oxide (N2O) emissions especially in Alfisols with claypans. Two trials (chapter 1-2) were conducted to evaluate the time of harvest of winter wheat (Triticum aestivum L.) or winter cereal rye (WCR; Secale cereale L.) to determine the best time of harvest for maximizing profit through improving biomass production at high quality. In chapter 1, a five site-yr trial was conducted in Colorado (CO) and Illinois (IL) to evaluate the effect of harvest date on WCR forage yield, quality, and its economic performance. From March to April, WCR dry matter (DM) yield increased exponentially in CO and linearly in IL. The DM yield at DOY 112-116 in CO was 6.9, 5.0, and 5.2 Mg ha-1 in 2018, 2019, and 2020, respectively compared to 4.7 and 2.7 Mg ha-1 in IL in 2019 and 2020. Delayed harvesting increased acid detergent fiber (ADF) and neutral detergent fiber (NDF) concentrations and decreased crude protein (CP), total digestible nutrients (TDN), and relative feed quality (RFQ). Yield-quality trade-off showed that forage yield increased rapidly but forage quality declined after DOY 105-108. Economic analysis, including cost of nutrient removal and 10% corn yield penalty following WCR production revealed harvesting WCR biomass as forage was economically feasible in four out of five site-yrs at hay price over 132 $ Mg-1. Eliminating corn yield penalty indicated profitability in four site-yrs at hay price of ≥110 $ Mg-1 and removing nutrient removal costs made all site-yrs profitable at hay price of ≥110 $ Mg-1. It was concluded that harvesting WCR biomass can be a profitable and effective strategy for sustainable intensification that can offer environmental stewardship and economic benefit. In chapter 2, a four-year trial was conducted in the 2017-2018, 2018-2029, 2019-2020, and 2020- 2021 growing seasons to evaluate the effect of harvesting time (late-March to mid-May considering the growth stage) on winter wheat biomass yield, quality, and farm profit in single season corn vs. wheat-corn rotation. A delay in harvest of wheat resulted in increased DM biomass and lower CP and RFQ. The RFQ that was suitable for dairy production occurred at GDD of 1849 in which the DM biomass was 6.2 Mg ha-1 leading to $1526.46 ha-1 income. The RFQ for heifer production was 126 at 2013 GDD in which the DM biomass was 6.8 Mg ha-1 leading to $1290.85 ha-1 income. These results suggested that wheat-corn rotation could provide extra income while covering the soil year-round. A series of trials were conducted to evaluate the effects of cover crop (CC) and nitrogen (N) management on (i) corn growth, (ii) grain yield and yield components, (iii) the economic optimum N rate (EONR) for corn and farm profit, (iv) N removal, and balances, (v) N use metrics, (vi) soil NO3-N and ammonium-N (NH4-N), along with (vii) N2O emissions and factors associated with it. In chapter 3, an experiment was conducted as a randomized complete block design with split plot arrangement and four replicates to study winter wheat cover crop management practices on corn growth, production, N requirement, soil N, and farm profit. The main plots were four CC treatments: no CC (control), early terminated wheat CC (four weeks to corn planting; ET), late terminated wheat CC (just prior to corn planting; LT), and harvested wheat CC (residue removal; RR), and the subplots were six N fertilizer application rates (0-280 kg N ha-1 ) for 2018 and 2019 and seven N fertilizer application rates (0-336 kg N ha-1 ) for 2020 and 2021. Wheat cover crop management influenced corn grain yield where fallow was consistently high yielding while RR decreased corn grain yield drastically due to its negative effects on the corn plant population. All cover crop treatments immobilized N as shown by lower corn grain yields at zero-N control compared to the fallow treatment. The EONR generally ranged from 151.4 kg ha-1 to 206.4 kg ha-1 in fallow, 192.8 kg ha-1 to 275.8 kg ha-1 in ET, 225 kg ha-1 to 325 kg ha-1 in LT, and 175.3 kg ha-1 to 257.5 kg ha-1 in RR. At the EONR, corn grain yields ranged from 12.2 Mg ha-1 to 13.7 Mg ha-1 in the fallow treatment, 9.7 Mg ha-1 to 13.0 Mg ha-1 in the ET, 9.51 Mg ha-1 to 13.3 Mg ha-1 in the LT, and 8.2 Mg ha-1 to 10.5 Mg ha-1 in the RR treatment. Adding N beyond EONR resulted in a drastic increase in end of season soil N which could be subject to leaching emphasizing targeting EONR is critical for avoiding high N leaching and that if N is applied at rates beyond EONR, then cover cropping becomes even a more critical practice to avoid N losses. In chapter 4 and 5, we evaluated whether splitting N fertilization along with the two (no-cover crop vs. early termination; ET) (chapter 4) or four above-mentioned cover crops treatments (chapter 5) could improve corn production and farm profit through improved N use efficiency (NUE). Therefore, for chapter 4, a two-yr field trail was implemented at the Agronomy Research Center in Carbondale, IL in 2018 and 2019 to evaluate whether split N application to corn changes N use efficiency (NUE) in no-cover crop vs. following an early terminated (ET) wheat cover crop. A four-replicated randomized completed block design with split plot arrangements were used. Main treatments were a no cover crop (control) vs. ET and subplots were five N timing applications to succeeding corn: (1) 168 kg N ha-1 at planting; (2) 56 kg N ha-1 at planting + 112 kg N ha-1 at sidedress; (3) 112 kg N ha-1 at planting + 56 kg N ha-1 at sidedress (4) 168 kg N ha-1 at sidedress, and (5) zero kg N ha-1 (control). Corn yield was higher in 2018 than 2019 reflecting more timely precipitation in that year. Grain yield declined by 12.6% following the wheat cover crop compared to no cover crop control indicating corn yield penalty when wheat was planted prior to corn. In 2018, a year with timely and sufficient rainfall, there were no differences among N application timing while in 2019, delaying the N addition improved NUE and corn grain yield due to excessive rainfall early in the season reflecting on N losses. Overall, our findings elucidate necessity of revisiting guidelines for current N management practices in Midwestern United States and incorporating cover crop component into MRTN prediction tool. For chapter 5, a four-year trial conducted with a split plot arrangement and four replicates. Main plots were four cover crop management [no cover crop control (fallow); ET, late termination (LT), and residue removal at late termination (RR) and five N fertilizer application timings (all at planting, most at planting + sidedress; half-half; less at planting and more at sidedress; and all sidedress). Our results indicated that RR resulted in corn population and grain yield reduction compared to other treatments. Fallow was consistently high-yielding and 112-56 N management during the first two years for fallow worked the best (10.1 Mg ha-1 ). In 2020 and 2021, both applying all N upfront or sidedressing yielded similar for fallow giving growers options with N timing. For both ET and LT, in all years, delaying the N addition to sidedress timing resulted in high yields (9.1 - 11.7 Mg ha-1 ). Some N addition upfront plus sidedressing the rest (56-168) resulted in the highest yield in ET in 2021 (11.6 Mg ha-1 ). For RR, split application of N (56-112 or 56-168) was consistently most productive in all years (8.7 Mg ha-1 ) suggesting that there is an advantage to sidedressing than upfront N application in cover crop systems. The high productive N management practices generally resulted in higher NUE (24.0 - 38.6 kg grain kg N-1 ) and lower N balance (20.6 - 50.2 kg ha-1 for 2018-2019, and 74 - 106.4 kg ha-1 for 2020-2021) which are critical to achieve not only for farm profit but also minimizing environmental footprints. Except for N0, N balance was positive in all treatments in all years indicating the inefficiency of fertilizer N that was corroborated by low NUE and PFP data. We concluded that to optimize corn production and reducing nutrient loss, split N addition or sidedressing N is most suitable especially in cover cropping systems. For chapter six, a four-times replicated randomized complete block design trial was conducted to evaluate the effects of winter wheat cover crop management practices (ET, LT, and RR) vs. a no-cover crop control (fallow) on corn grain yield, N removal and balances, soil N dynamics, soil volumetric water content (VWC) and temperature dynamics, N2O-N emissions, yield-scaled N2O-N emissions, and factors that drive N2O-N and corn grain yield in 2019-2020 and 2020-2021 growing seasons in a silt loam soil with clay and fragipans. Our results indicated that corn grain yield decreased by both ET and RR as compared to the fallow and LT. Soil temperature was similar among all treatments, but soil VWC was higher in LT and ET than fallow and RR. The LT treatment always had lower soil NO3-N than the other treatments in both years. In 2021, the ET also had less soil nitrate-N than fallow and RR. Averaged over the two years, cumulative soil N2O-N was higher in LT (14.85 kg ha-1 ) and ET (12.85 kg ha-1 ) than RR (11.10 kg ha-1 ) and fallow (7.65 kg ha-1 ) indicating while these treatments are effective in reducing NO3-N leaching, they could increase soil N2O-N emissions. Principal component analysis indicated that higher N2O-N emissions in LT and ET was related to higher VWC suggesting at optimal N management scenarios, other factors than soil N drive N2O-N emissions. In this study, fallow had the least yield-scaled N2O-N emissions followed by RR. The yield-scaled emissions were similar between ET and LT. These results indicate the importance of evaluating N2O-N emissions in cereal cover crops prior to corn for informing best management practice for winter cereal cover crop adoption. Future studies should focus on manipulating cover crop management to capture residual N without creating microclimates with high VWC to avoid increase of N2O-N emissions. While a lot is known about CC effects on the following cash crop, less is known about rotational benefits of late terminated (planting green) wheat and nitrogen (N) management on the following WCR and soybean in rotation. Therefore, for chapter 7, a trial was conducted with a split plot arrangement in a randomized complete block design set up. The main plots were two cover crop treatments (a no cover crop control vs. LT) and the subplots were three N rates [0 (N0), 224 (N224), and 336 (N336) kg N ha-1 ). Each treatment was replicated four times and rye and soybean was planted in all of the plots in rotation. Our results indicated wheat, when terminated late, can uptake 50-80 kg N ha-1 and result in belowground:aboveground ratio of 0.18 in which belowground had much higher C:N than the aboveground biomass. The soil NO3-N was affected by wheat presence and often reduced due to wheat N uptake and also N immobilization negatively affecting the following corn especially at both N0 and N224. Nitrogen fertilization at 336 kg N ha-1 resulted in high end of season N, reduced NUE, increased N balance, and thus, potential for N loss especially in the fallow treatment. The end of season N was lower and NUE was higher in LT which was coincided with reduced rye N uptake in LT suggesting wheat effect lingers longer than just during the corn season and could potentially reduce N loss potential during the fallow period following corn harvest. Soybean yields were higher in LT than the fallow which could be due to (i) higher rye biomass in fallow or (ii) positive legacy effect of wheat in rotation. Improved soybean yields could offset some of the economic loss during the corn phase and push growers in the Midwestern USA to be willing to adopt cover cropping to minimize N loss while protecting soil and stay profitable. Our results from chapter 3-7, indicate a need to change in cover crop management strategy to make it more user friendly with lower costs. In general, in the Midwestern USA, growers are reluctant to plant WCR especially prior to corn due to N immobilization and establishment issues. Precision planting of WCR or --Skipping the corn row‖ (STCR) can minimize some issues associated with WCR ahead of corn while reducing cover crop seed costs. The objective of this study was to compare the effectiveness of --STCR‖ vs. normal planting of WCR at full seeding rate (NP) on WCR biomass, nutrient uptake, and composition in three site-yrs (ARC2019, ARC2020, BRC2020). Our results indicated no differences in cover crop dry matter (DM) biomass production between the STCR (2.40 Mg ha-1 ) and NP (2.41 Mg ha-1 ) supported by similar normalized difference vegetative index (NDVI) and plant height for both treatments. Phosphorus, potassium (K), calcium (Ca), and magnesium (Mg) accumulation in aboveground biomass was only influenced by site-yr and both STCR and NP removed similar amount of P, K, Ca, and Mg indicating STCR could be as effective as NP in accumulating nutrients. Aboveground carbon (C) content (1086.26 kg h-1 average over the two treatments) was similar between the two treatments and only influenced by site-yr differences. Lignin, lignin:N, and C:N ratios were higher in STCR than NP in one out of three site-years (ARC2019) indicating greater chance of N immobilization when WCR was planted later than usual. Implementing STCR saved 8.4 $ ha-1 for growers and could incentivize growers to adopt this practice. Future research should evaluate corn response to STCR compared with NP and assess if soil quality declines by STCR practice over time.
Book Synopsis The Impacts of Continuous Corn and a Corn-corn-soybean-wheat Rotation Grown Under Various Management Schemes on Nitrate Leaching, Soil Physical Characteristics, and Net Returns by : Jeffrey Smeenk
Download or read book The Impacts of Continuous Corn and a Corn-corn-soybean-wheat Rotation Grown Under Various Management Schemes on Nitrate Leaching, Soil Physical Characteristics, and Net Returns written by Jeffrey Smeenk and published by . This book was released on 2003 with total page 216 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis An Analysis of Carbon Sequestration Rates and the Implications of Cover Crops by : Sara G. Martin
Download or read book An Analysis of Carbon Sequestration Rates and the Implications of Cover Crops written by Sara G. Martin and published by . This book was released on 2023 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: As the population increases, the agriculture industry is faced with the rising challenge of meeting food demand. With increased production, environmental pressures will likely increase. Because of the potential impact agriculture and conventional systems have on the environment, the industry must implement more sustainable practices. Agricultural sources have been indicated as some of the sources of greenhouse gas emissions, which have consistently caused global average temperatures to increase by 0.1 degree Celsius per decade for multiple decades, with concomitant impacts on the CO2 levels in the atmosphere as well as the sea level. Soil degradation, water pollution, air pollution, and greenhouse gas emissions are related issues that are affecting the environment, and the agriculture industry works to find methods to reduce any potential negative impacts from farm and ranch operations and food processors. Among the market-based strategies for addressing these negative impacts, carbon sequestration and trading have become two widely popular incentives to be used to control the amount of greenhouse gas emissions. This method of incentivizing the storage of carbon can lead to an increased economic value of agricultural management practices, which provide soil ecosystem services through soil organic carbon (SOC). A major management practice recommended for increasing SOC storage is the adoption of cover crops. Cover crops have been acknowledged and developed for over 3,000 years; however, more research is still required to help find the best solutions to fit the needs of increased food production. This thesis will focus on the analysis of previous studies regarding carbon sequestration. In this analysis, specific topics of interest will include: i) the impact of the agriculture industry on climate change; ii) a summary of data on carbon sequestration rates on specific crops; iii) the estimated amounts of carbon sequestration in selected states, and iv) the impacts of cover crop implementation on soil carbon sequestration rates. This comprehensive review may be utilized in educational efforts on the adoption of and sustainable benefits of conservation agriculture, including the implications of cover crops.
Book Synopsis Interseeding Cover Crops in Corn by : Aaron Patrick Brooker
Download or read book Interseeding Cover Crops in Corn written by Aaron Patrick Brooker and published by . This book was released on 2019 with total page 331 pages. Available in PDF, EPUB and Kindle. Book excerpt: Farmers could enhance crop diversity in their farming systems by interseeding cover crops in corn in late May and June in corn rotations in the Upper Midwest. Recommendations must be developed for cover crop species, seeding rates, and interseeding timings that optimize cover crop growth and enhance corn production. Weeds must be controlled, and cover crops must establish in this system. Cover crops influence soil health in long term studies; however, the influence of interseeded cover crops on soil enzymes, soil structure, and nutrient cycling has not been reported. In Michigan, two experiments were conducted from 2015-2017 and one experiment from 2017-2019. In the first experiment, annual ryegrass, crimson clover, oilseed radish and a mixture of the three species were broadcast interseeded at each of the V1 through V7 corn stages at a single seeding rate. Cover crop and weed density and biomass were measured during the growing season, at the time of corn harvest, and the following spring. Soil samples were taken in the spring in the year following interseeding and analyzed for inorganic N, extracellular enzyme activity, and aggregate stability. Corn was planted as an indicator crop and sampled for C and N content. In the second experiment, preemergence (PRE) and postemergence (POST) herbicides were applied, and cover crops interseeded at the V3 and V6 corn stages. Cover crops were evaluated in October for injury and stand loss. A greenhouse trial was also included to evaluate cover crop response to herbicides. In the third experiment, the same three cover crop species and a mixture of annual ryegrass and crimson clover were interseeded at three seeding rates in V3 and V6 corn. Establishment, biomass, and corn grain yield were collected using the same methods as previously described. Eight on-farm locations were interseeded with the same cover crop species at the 1X rate at the V3 and V6 corn stages. All plots were flown with a fixed-wing aircraft to measure canopy temperature. Small-plots were flown with UAV to acquire multispectral imagery to determine NDVI and NDRE. In years with normal or below normal precipitation, annual ryegrass and oilseed radish produced the highest biomass. Establishment improved when seeding on tilled soil compared with no-till soil. All cover crop species established, regardless of tillage, with above normal rainfall. Both annual ryegrass and crimson clover established when interseeded as a mixture at the seeding rates used. Increasing seeding rates usually increased biomass production. Cover crops could be interseeded at any time from V1-V7 corn if weeds were controlled. No cover crop species was competitive with summer annual weeds; annual ryegrass was the only species that overwintered and suppressed winter annual weeds. There were PRE and POST options for weed control with all cover crop species, but farmers must be mindful of herbicide and cover crop combinations. Delaying interseeding until V6 may reduce injury from some PRE herbicides. In the year of interseeding, cover crops did not reduce corn grain yield; therefore, remote imagery was not able to detect changes in corn health. Remote imagery detected cover crop establishment in the V3 interseedings prior to corn canopy closure; remote imagery did not detect less thermal stress where cover crops were interseeded. Annual ryegrass plots had reduced spring inorganic N content, and this sometimes translated to reduced N in the indicator corn crop. Success of broadcast interseeded cover crops is highly depended on adequate precipitation; this practice would be especially successful where summer rainfall is consistent or in irrigated systems. Benefits of cover crops are likely to be realized over multiple years of interseeding; farmers must balance goals of cover cropping with costs of seeding when selecting species, seeding rates, and weed control options.
Book Synopsis Using Cover Crops in Wheat-Corn Rotations to Provide Forage While Improving Soil by : Sabra Lynn Gerdes
Download or read book Using Cover Crops in Wheat-Corn Rotations to Provide Forage While Improving Soil written by Sabra Lynn Gerdes and published by . This book was released on 2017 with total page 108 pages. Available in PDF, EPUB and Kindle. Book excerpt:
Book Synopsis The Effects of Grazing Cover Crops on Animal Performance, Soil Characteristics, and Subsequent Soybean Production in East-central Mississippi by : Bronson Scott Bass
Download or read book The Effects of Grazing Cover Crops on Animal Performance, Soil Characteristics, and Subsequent Soybean Production in East-central Mississippi written by Bronson Scott Bass and published by . This book was released on 2021 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: Integrated crop-livestock systems (ICLS) incorporate cropping systems and livestock production by grazing cover crops. With a growing awareness in recent years regarding agricultural sustainability, these systems have begun to be re-introduced into the southeastern U.S. This study evaluated cover cropping systems under grazed no-till (GNT), un-grazed no-till (UNT), and un-grazed conventional tillage (UCT) management, in Mississippi. Beef cattle (Bos spp.) performance was significantly less in the cover crop treatment of oats (Avena sativa) + crimson clover (Trifolium incarnatum) + radish (Raphanus sativus; OCR) in both average daily gain (ADG; 3.03 lb hd−1 d−1) and total gain ac−1 (GAIN; 346 lb ac−1). Soybean (Glycine max) yield was unaffected by cover crop treatment and tillage. The lowest expected economic return was generated by OCR ($749.31 ac−1). Soil penetration resistance was unaffected by the influence of grazing. The greatest concentrations of soil organic carbon (1.44%) and soil nitrogen (0.20%) were observed in GNT.
