Targeting perennial vegetation in agricultural landscapes for enhancing ecosystem services

Asbjornsen, Heidi; Hernández‐Santana, Virginia; Liebman, Matt; Bayala, Jules; Chen, Jiquan; Helmers, Matthew J.; Ong, C. K.; Schulte, Lisa A.

doi:10.1017/s1742170512000385

Cited by 225 publications

(177 citation statements)

References 305 publications

(380 reference statements)

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“…Schulte et al 18 suggested that the strategic integration of perennial vegetation into agricultural landscapes dominated by annual crops could help reconcile agricultural productivity with environmental quality. Increasing crop and non-crop diversity in agroecosystems with perennial species may be especially important because perennial plants perform many key ecological functions more effectively than annuals, including (1) regulating the flow and storage of water, (2) reducing soil erosion, (3) storing and cycling nutrients and carbon, and (4) providing habitat for natural enemies of crop pests and for native plants and animals of conservation concern 18,19 . Many options exist for diversifying agroecosystems with perennial vegetation, including forage crops that are alternated with row crops in rotation sequences; riparian buffers of trees, shrubs and grasses that separate crop fields from streams; in-field strips of herbaceous species that filter runoff water; trees and shrubs on field margins that reduce wind movement; reconstructed wetlands that receive drainage water from crop fields; agroforestry plantations that supply a variety of economic products; and woody and herbaceous plants that are harvested as biofuel feedstocks 18 .…”

Section: Introductionmentioning

confidence: 99%

Using biodiversity to link agricultural productivity with environmental quality: Results from three field experiments in Iowa

Liebman

Helmers

Schulte

et al. 2013

Renew. Agric. Food Syst.

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Agriculture in the US Corn Belt is under increasing pressure to produce greater quantities of food, feed and fuel, while better protecting environmental quality. Key environmental problems in this region include water contamination by nutrients and herbicides emitted from cropland, a lack of non-agricultural habitat to support diverse communities of native plants and animals, and a high level of dependence on petrochemical energy in the dominant cropping systems. In addition, projected changes in climate for this region, which include increases in the proportion of precipitation coming from extreme events could make soil and water conservation in existing cropping systems more difficult. To address these challenges we have conducted three cropping systems projects in central Iowa: the Marsden Farm Cropping Systems experiment, the Sciencebased Trials of Row-crops Integrated with Prairies (STRIPs) experiment, and the Comparison of Biofuel Systems (COBS) experiment. Results from these experiments indicate that (1) diversification of the dominant corn-soybean rotation with small grains and forage legumes can permit substantial reductions in agrichemical and fossil hydrocarbon use without compromising yields or profitability; (2) conversion of small amounts of cropland to prairie buffer strips can provide disproportionately large improvements in soil and water conservation, nutrient retention, and densities of native plants and birds; and (3) native perennial species can generate large amounts of biofuel feedstocks and offer environmental benefits relative to corn-and soybean-based systems, including greater carbon inputs to soil and large reductions in nitrogen emissions to drainage water. Increasing biodiversity through the strategic integration of perennial plant species can be a viable strategy for reducing reliance on purchased inputs and for increasing agroecosystem health and resilience in the US Corn Belt. AbstractAgriculture in the US Corn Belt is under increasing pressure to produce greater quantities of food, feed and fuel, while better protecting environmental quality. Key environmental problems in this region include water contamination by nutrients and herbicides emitted from cropland, a lack of non-agricultural habitat to support diverse communities of native plants and animals, and a high level of dependence on petrochemical energy in the dominant cropping systems. In addition, projected changes in climate for this region, which include increases in the proportion of precipitation coming from extreme events could make soil and water conservation in existing cropping systems more difficult. To address these challenges we have conducted three cropping systems projects in central Iowa: the Marsden Farm Cropping Systems experiment, the Science-based Trials of Row-crops Integrated with Prairies (STRIPs) experiment, and the Comparison of Biofuel Systems (COBS) experiment. Results from these experiments indicate that (1) diversification of the dominant corn-soybean rotation with small grains and fo...

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Section: Introductionmentioning

confidence: 99%

Using biodiversity to link agricultural productivity with environmental quality: Results from three field experiments in Iowa

Liebman

Helmers

Schulte

et al. 2013

Renew. Agric. Food Syst.

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“…Perennial crops contribute to a mixture of population communities with different "ecological ages", which was proposed by Odum [147] for nature conservation in landscape planning [153]. A strategic placement of perennial plants in agricultural landscapes, either on-field or adjacent, likely provides greater benefits than their spatial extent suggests [11,122].…”

Section: Potentials For Nature Conservationmentioning

confidence: 99%

Supporting Agricultural Ecosystem Services through the Integration of Perennial Polycultures into Crop Rotations

et al. 2017

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This review analyzes the potential role and long-term effects of field perennial polycultures (mixtures) in agricultural systems, with the aim of reducing the trade-offs between provisioning and regulating ecosystem services. First, crop rotations are identified as a suitable tool for the assessment of the long-term effects of perennial polycultures on ecosystem services, which are not visible at the single-crop level. Second, the ability of perennial polycultures to support ecosystem services when used in crop rotations is quantified through eight agricultural ecosystem services. Legume-grass mixtures and wildflower mixtures are used as examples of perennial polycultures, and compared with silage maize as a typical crop for biomass production. Perennial polycultures enhance soil fertility, soil protection, climate regulation, pollination, pest and weed control, and landscape aesthetics compared with maize. They also score lower for biomass production compared with maize, which confirms the trade-off between provisioning and regulating ecosystem services. However, the additional positive factors provided by perennial polycultures, such as reduced costs for mineral fertilizer, pesticides, and soil tillage, and a significant preceding crop effect that increases the yields of subsequent crops, should be taken into account. However, a full assessment of agricultural ecosystem services requires a more holistic analysis that is beyond the capabilities of current frameworks.

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“…Much of the dysfunction of industrial agriculture in the Corn Belt derives from the low levels of biological diversity now present across landscapes and within farming systems in the region (Broussard and Turner, 2009;Liebman et al, 2013;Asbjornsen et al, 2014). Of particular importance is the fact that shallow-rooted, short-season crops like corn and soybean have replaced native, perennial species whose deep roots and long growth period from early spring to late fall are much more effective in holding soil in place, promoting water infiltration into soil and transpiration into the atmosphere, fostering carbon sequestration and nutrient retention, and providing habitat for pollinators, biological control agents, and a host of other organisms .…”

mentioning

confidence: 99%

“…Although we have presented just two case studies of how diversification might be used to enhance agroecosystem performance and resilience in the U.S. Corn Belt, studies conducted in other regions also support diversification as a key principle underpinning the design of multifunctional agroecosystems that provide a wide range of goods and services while protecting environmental quality (Altieri, 1995;Kremen and Miles, 2012;Asbjornsen et al, 2014). Additional options for diversifying landscapes and cropping systems include the use of mixed species pastures for dairy and beef production (Sulc and Tracy, 2007); perennial grains for food and feed production (Cox et al, 2006); cover crops to fill otherwise unoccupied temporal niches (Snapp et al, 2005); dedicated perennial grasses and native mixed-species communities for biofuel feedstock production (Heaton et al, 2013); herbaceous and woody species for reconstructing wetlands (Zedler, 2003) and riparian corridors (Schultz et al, 2004); and trees for agroforestry plantations ( Jose et al, 2012).…”

mentioning

confidence: 99%

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Enhancing agroecosystem performance and resilience through increased diversification of landscapes and cropping systems

Liebman

Schulte

2015

Elementa: Science of the Anthropocene

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Targeting perennial vegetation in agricultural landscapes for enhancing ecosystem services

Cited by 225 publications

References 305 publications

Using biodiversity to link agricultural productivity with environmental quality: Results from three field experiments in Iowa

Using biodiversity to link agricultural productivity with environmental quality: Results from three field experiments in Iowa

Supporting Agricultural Ecosystem Services through the Integration of Perennial Polycultures into Crop Rotations

Enhancing agroecosystem performance and resilience through increased diversification of landscapes and cropping systems

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