Evaluation of Grass and Legume Species as Perennial Ground Covers in Corn Production

Flynn, E. Scott; Moore, Kenneth J.; Singer, Jeremy W.; Lamkey, Kendall R.

doi:10.2135/cropsci2011.06.0306

Cited by 22 publications

(47 citation statements)

References 19 publications

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“…These findings are consistent with earlier reports, which found that consistent and uniform maize stands in maize-sod systems were challenging to achieve (Stanley and Gallaher, 1980), observed delayed maturity in intercropped maize (Kloeke et al, 1989) and reported that greater LM cover generally resulted in lower maize plant density than the control (Flynn et al, 2013). Observed reductions in plant density in the no LM treatment maize with residue retention versus no LM treatment maize with residue removal are consistent with other reports regarding lower emergence rates for maize treatments with residue retention across various tillage methods (Dam et al, 2005) and reduced maize plant growth when the maize plant was in close proximity to residue (Yakle and Cruse, 1983).…”

Section: Maize Maturity and Plant Densitysupporting

confidence: 93%

“…The maize grain yield reduction for LM treatment maize is similar to other reports in that excessive competition from LM resulted in lower grain yield than conventional maize (Adams et al, 1970;Carreker et al, 1972;Robertson et al, 1976;Flynn et al, 2013). In the SM sequence at Boone, the yield-stable hybrid produced greater total aboveground biomass in no LM treatments than LM treatments, at 20.20 and 14.33 Mg ha −1 , respectively.…”

Section: Maize Total Aboveground Biomass Stover Yield Grain Yield supporting

confidence: 83%

“…In the SM sequence at Boone, the yield-stable hybrid produced greater total aboveground biomass in no LM treatments than LM treatments, at 20.20 and 14.33 Mg ha −1 , respectively. Previous reports attribute observed yield suppression of maize in LM to early-season stresses (Flynn et al, 2013;Bartel et al, 2017). Box et al (1980) observed that maize grain yield was lower in strip-killed sod than completely killed sod, and while water availability was not a limitation, observed differences may have been due to phytotoxicity.…”

Section: Maize Total Aboveground Biomass Stover Yield Grain Yield mentioning

confidence: 84%

“…Although grain yield reductions were still documented in the LM treatment maize, Poa and Festuca species were identified as compatible groundcovers for a maize row crop system (Flynn et al, 2013). Although grain yield reductions were still documented in the LM treatment maize, Poa and Festuca species were identified as compatible groundcovers for a maize row crop system (Flynn et al, 2013).…”

mentioning

confidence: 97%

“…Living mulch (LM) offers a potential solution for reconciling stover removal with natural resources preservation, and grass species have been evaluated for their use as LM. Although grain yield reductions were still documented in the LM treatment maize, Poa and Festuca species were identified as compatible groundcovers for a maize row crop system (Flynn et al, 2013). Substantial benefits of cover crops in a natural resources management capacity occur through diminished soil erosion, enhanced soil fertility, and water infiltration (Teasdale, 1996).…”

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confidence: 99%

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Living Mulch for Sustainable Maize Stover Biomass Harvest

et al. 2017

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3273ReseaRch M aize (Zea mays L.) stover is harvested for a variety of uses, including as a feedstock for cellulosic ethanol production or for use in livestock operations as bedding or feed. The use of 136 billion L yr −1 of renewable fuels by 2022 is mandated by the Renewable Fuel Standard as established in the Energy Independence and Security Act of 2007, of which cellulosic biofuels would comprise 61 billion L (USDOE, 2011). The promulgated rules identify maize stover as a cellulosic biofuels feedstock (Schnepf, 2013), thus expanding long-term opportunities for stover as an additional revenue stream in the renewable fuels arena. Other uses also enhance the economic incentive to harvest maize stover. For example, chemical processing of residues can increase digestibility by 35 to 62% by decomposition of lignocellulosic bonds (Shreck et al., 2011), making maize stover more attractive for use as a livestock feed, especially when grain prices escalate (Meteer, 2014). The increased harvest of maize stover, however, compounds the already hefty challenges of natural resources conservation in conventional systems.Maize stover provides myriad ecosystems services, and returning stover to soil recycles plant nutrients. Standard fertilization practices can be insufficient to compensate for nutrient loss after residue removal or when soil erosion approaches the soil loss ABSTRACT The Renewable Fuels Standard mandate provides enhanced opportunity for maize (Zea mays L.) stover use as a bioenergy feedstock. Living mulch (LM) offers a possible solution for the natural resources constraints associated with maize stover biomass harvest. A two-site-year study was conducted near Boone and Kanawha, IA, in both maize following maize (MM) and maize following soybean [Glycine max (L.) Merr.] (SM) sequences to evaluate the impact of established and chemically suppressed Kentucky bluegrass (Poa pratensis L.) 'Ridgeline', 'Wild Horse', 'Oasis', and 'Mallard' blend and creeping red fescue (Festuca rubra L.) 'Boreal' as LM on three maize hybrids (population sensitive, population insensitive, and yield stable). Maize grain yield for the no LM treatments in the MM and SM sequences was 12.0 and 13.2 Mg ha −1 , respectively, at Boone and 12.8 and 14.8 Mg ha −1 , respectively, at Kanawha, 23 to 73% greater than the LM treatment. Ethanol yield (L ha −1 ) was 12 to 119% greater, protein concentration was £9% greater, and starch concentration was £1% lower in the no LM treatment maize than in LM treatment maize. Maize hybrid by cover interaction was significant for parameters including total aboveground biomass and protein concentration at Boone, with inconsistent maize hybrid responses to the LM system. Stover yield, stover quality, stover C and N, leaf area index, maize plant density, maize maturity, and sequence year in the MM sequence were also evaluated. Results emphasize the need for maize hybrid and LM system compatibility, as well as effective LM suppression techniques.

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Section: Maize Maturity and Plant Densitysupporting

confidence: 93%

Section: Maize Total Aboveground Biomass Stover Yield Grain Yield supporting

confidence: 83%

Section: Maize Total Aboveground Biomass Stover Yield Grain Yield mentioning

confidence: 84%

mentioning

confidence: 97%

mentioning

confidence: 99%

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Living Mulch for Sustainable Maize Stover Biomass Harvest

et al. 2017

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Modeling perennial groundcover effects on annual maize grain crop growth with the Agricultural Production Systems sIMulator

et al. 2020

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The inclusion of perennial groundcover (PGC) in maize (Zea mays L.) production offers a tenable solution to natural resources-related concerns associated with conventional maize; however, insight into system management and key information gaps is needed to guide future research. We therefore extended the Agricultural Production Systems sIMulator (APSIM) to an annual and perennial intercrop by integrating annual and perennial APSIM modules. These were parameterized for Kentucky bluegrass (Poa pratensis L.) or creeping red fescue (Festuca rubra L.) as PGC using a 3-yr dataset. Our objectives for this intercropping modeling study were to: (a) simultaneously model a PGC and annual cash crop using APSIM software; (b) utilize APSIM to understand interactive processes in the maize-PGC system; and (c) utilize the calibrated model to explore both production and environmental benefits via scenario modeling. For the first objective, the integrated model successfully predicted maize total aboveground biomass (relative root mean square error [RRMSE] of 13-27%) and PGC above-and belowground tissue N concentration (RRMSE of 11-18%). The calibrated model captured observed trends in PGC biomass accumulation and soil nitrate. For the second objective, model analysis showed that competition for light was the primary PGC-related maize yield-penalty factor, while water and N affected maize yield later in the growing season. In the third objective, we concluded that effective PGC suppression produces minimal maize-yield loss and significant environmental benefits; conversely, poor groundcover suppression may produce unfavorable environmental consequences and decrease maize grain yield. Effective PGC suppression is key for long-term system success.

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Evaluating cool‐season grass species as potential perennial groundcover for maize production

et al. 2022

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Removal of crop residue poses negative consequences for soil health, nutrient leaching, and runoff. Perennial groundcovers (PGC) provide a method of maintaining soil health while allowing the sustainable intensification of maize (Zea mays L.) systems for biofuel production by providing groundcover for several years. However, previous studies have only evaluated a few varieties of PGC. We conducted a 2‐yr study to evaluate the compatibility of cool‐season turfgrass PGCs under maize. Maize was interplanted into 20 accessions of Kentucky bluegrass (Poa pratensis L.), Sandberg bluegrass (Poa secunda J. Presl), and red fescue (Festuca rubra L.) in a randomized complete block design in Boone, IA. Data on maize grain yield, maize grain quality, and ground coverage of PGC were collected. There were no differences in maize grain yield across species in 2017. In 2018, maize grain yield under red fescue was 1.0, 1.8, and 2.1 Mg ha–1 less than Kentucky bluegrass, Sandberg bluegrass, or the no‐grass control, respectively. Maize under red fescue produced 2.3, 4.8, and 3.9 g kg–1 more protein than Kentucky bluegrass, Sandberg bluegrass, and the no‐grass control, but produced 878 L ha–1 and 758 L ha–1 less ethanol than the no‐grass control and Sandberg bluegrass, respectively. In both years, Kentucky bluegrass groundcover declined approximately 22%, while Sandberg bluegrass groundcover remained below 10%. Red fescue maintained groundcover over 22% in 2017 and 34% in 2018. These results indicate that maize under Kentucky bluegrass and Sandberg bluegrass can perform similarly to conventional maize.

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Evaluation of Grass and Legume Species as Perennial Ground Covers in Corn Production

Cited by 22 publications

References 19 publications

Living Mulch for Sustainable Maize Stover Biomass Harvest

Living Mulch for Sustainable Maize Stover Biomass Harvest

Modeling perennial groundcover effects on annual maize grain crop growth with the Agricultural Production Systems sIMulator

Evaluating cool‐season grass species as potential perennial groundcover for maize production

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