Regenerating Agricultural Landscapes with Perennial Groundcover for Intensive Crop Production

Moore, Ken; Anex, Robert P.; Elobeid, Amani; Fei, Shuizhang; Flora, Cornelia Butler; Goggi, A. Susana; Jacobs, Keri; Jha, Prashant; Kaleita, Amy L.; Karlen, Douglas L.; Laird, David A.; Lenssen, Andrew W.; Lübberstedt, Thomas; McDaniel, Marshall D.; Raman, D. Raj; Weyers, Sharon L.

doi:10.3390/agronomy9080458

Cited by 35 publications

(40 citation statements)

References 165 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…This range of diversity is interesting because subspecies freely intercross at a ploidy level. Wild populations that are under-represented in breeding pools ( Muller et al, 2006 ) could be used to integrate some traits for adaptation to new constraints, such as climate change, or new practices, such as cover crops ( Labreuche, 2017 ; Moore et al, 2019 ). These accessions were studied in seven temperatures ranging from 5°C, a temperature which mimics cold autumns or springs, to a temperature of 40°C, which could occur with late spring sowings under warm climates.…”

Section: Discussionmentioning

confidence: 99%

The History of Domestication and Selection of Lucerne: A New Perspective From the Genetic Diversity for Seed Germination in Response to Temperature and Scarification

et al. 2021

View full text Add to dashboard Cite

Lucerne (Medicago sativa), a major perennial pasture legume, belongs to a species complex that includes several subspecies with wild and cultivated populations. Stand establishment may be compromised by poor germination. Seed scarification, deterioration and temperature have an impact on germination. The objective of this study was to analyse the genetic diversity of lucerne germination in response to three factors: (1) temperature, with seven constant temperatures ranging from 5 to 40°C, was tested on 38 accessions, (2) seed scarification was tested on the same accessions at 5 and 22°C, (3) seed deterioration was tested on two accessions and two seed lots at the seven temperatures. The germination dynamics of seed lots over time was modelled and three parameters were analysed: germinability (germination capacity), maximum germination rate (maximum% of seeds germinating per time unit), and lag time before the first seed germinates. Seed scarification enhanced germinability at both temperatures and its effect was much higher on falcata and wild sativa accessions. Incomplete loss of the hardseededness trait during domestication and selection is hypothesised, indicating that the introduction of wild material in breeding programmes should be followed by the selection for germinability without scarification. Seed lots with altered germinability had low germination at extreme temperatures, both cold and hot, suggesting that mild temperatures are required to promote germination of damaged seed lots. A large genetic diversity was revealed for germination (both capacity and rate) in response to temperature. All accessions had an optimal germination at 15 or 22°C and a poor germination at 40°C. The sativa varieties and landraces had a high germination from 5 to 34°C while the germination of falcata and the wild sativa accessions were weakened at 5 or 34°C, respectively. These differences are interpreted in terms of adaptation to the climate of their geographical origin regions in order to escape frost or heat/drought risks. These new findings give insights on adaptation and domestication of lucerne in its wide geographic area. They suggest further improvement of germination is needed, especially when introducing wild material in breeding pools to remove scarification requirements and to limit differences in response to temperature.

show abstract

Section: Discussionmentioning

confidence: 99%

The History of Domestication and Selection of Lucerne: A New Perspective From the Genetic Diversity for Seed Germination in Response to Temperature and Scarification

et al. 2021

View full text Add to dashboard Cite

show abstract

“…Grassland and pastures together could offset all farm emissions on site, whereas shrublands, corn, wheat and soybean fields took up the least amount of carbon, due to their shorter growing season (Supplementary Materials Figure S4), thus more area would be needed to offset farm emissions. Corn and soybean production systems may also be unsustainable due to their impact on SOC losses [82], as their root:shoot ratios are comparatively small [38], adding little to increase soil carbon stocks [69,83,84]. Furthermore, the management of corn fields at the Prairie du Sac dairy farm accumulated limited soil C because residues left on site were negligible, as the majority of the crop biomass was chopped for silage or baled for bedding following corn grain harvest.…”

Section: Iclss For Managing Dairy Ghg Emissionsmentioning

confidence: 99%

Increasing Dairy Sustainability with Integrated Crop–Livestock Farming

et al. 2020

View full text Add to dashboard Cite

Dairy farms are predominantly carbon sources, due to high livestock emissions from enteric fermentation and manure. Integrated crop–livestock systems (ICLSs) have the potential to offset these greenhouse gas (GHG) emissions, as recycling products within the farm boundaries is prioritized. Here, we quantify seasonal and annual greenhouse gas budgets of an ICLS dairy farm in Wisconsin USA using satellite remote sensing to estimate vegetation net primary productivity (NPP) and Intergovernmental Panel on Climate Change (IPCC) guidelines to calculate farm emissions. Remotely sensed annual vegetation NPP correlated well with farm harvest NPP (R2 = 0.9). As a whole, the farm was a large carbon sink, owing to natural vegetation carbon sinks and harvest products staying within the farm boundaries. Dairy cows accounted for 80% of all emissions as their feed intake dominated farm feed supply. Manure emissions (15%) were low because manure spreading was frequent throughout the year. In combination with soil conservation practices, ICLS farming provides a sustainable means of producing nutritionally valuable food while contributing to sequestration of atmospheric CO2. Here, we introduce a simple and cost-efficient way to quantify whole-farm GHG budgets, which can be used by farmers to understand their carbon footprint, and therefore may encourage management strategies to improve agricultural sustainability.

show abstract

“…provides winter cover while producing biomass for biofuel production [9,10]. An emerging approach is to intercrop maize with a perennial groundcover [11]. In these systems, perennial species such as kentucky bluegrass (Poa pratensis L.), creeping red fescue (Festuca rubra L.), kura clover (Trifolium ambiguum M.…”

Section: Potential For Providing Food Bioenergy and Conservation Bementioning

confidence: 99%

“…Bieb. ), and white clover (Trifolium repens L.) are grown primarily for environmental reasons, but in some cases are harvested as a forage crop [11][12][13]. Growing maize with perennial groundcover more than doubles the quantity of biomass that can be sustainably harvested in this system, significantly increasing the density of biomass available within a fuel shed and thereby reducing haul distance and transportation costs.…”

Section: Potential For Providing Food Bioenergy and Conservation Bementioning

confidence: 99%

A Midwest USA Perspective on Von Cossel et al.’s Prospects of Bioenergy Cropping Systems for a More Social-Ecologically Sound Bioeconomy

2020

Self Cite

View full text Add to dashboard Cite

Bioenergy cropping systems afford the prospect to provide a more socially and ecologically sustainable bioeconomy. By creating opportunities to diversify agroecosystems, bioenergy crops can be used to fulfill multiple functions in addition to providing more environmentally benign fuels. Bioenergy crops can be assembled into cropping systems that provide both food and energy and which also provide cleaner water, improved soil quality, increased carbon sequestration, and increased biological diversity. In so doing, they improve the resilience of agroecosystems and reduce risks associated with climate change. Beyond the farmgate, bioenergy crops can improve the economic prospects of rural communities by creating new jobs and providing opportunities for local investment.

show abstract

Regenerating Agricultural Landscapes with Perennial Groundcover for Intensive Crop Production

Cited by 35 publications

References 165 publications

The History of Domestication and Selection of Lucerne: A New Perspective From the Genetic Diversity for Seed Germination in Response to Temperature and Scarification

The History of Domestication and Selection of Lucerne: A New Perspective From the Genetic Diversity for Seed Germination in Response to Temperature and Scarification

Increasing Dairy Sustainability with Integrated Crop–Livestock Farming

A Midwest USA Perspective on Von Cossel et al.’s Prospects of Bioenergy Cropping Systems for a More Social-Ecologically Sound Bioeconomy

Contact Info

Product

Resources

About