Perennial Filter Strips Reduce Nitrate Levels in Soil and Shallow Groundwater after Grassland‐to‐Cropland Conversion

Zhou, Xiaobo; Helmers, Matthew J.; Asbjornsen, Heidi; Kolka, Randy; Tomer, Mark D.

doi:10.2134/jeq2010.0151

Cited by 59 publications

(96 citation statements)

References 44 publications

(47 reference statements)

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“…The application of N fertilizers and wet field conditions likely contributed to the high NO 3 -N concentration in the spring of the corn years (2008 and 2010). High groundwater table (Zhou et al 2010). Return flows of shallow groundwater to the surface can dominate the late recession of a runoff hydrograph.…”

Section: Resultsmentioning

confidence: 99%

“…The two watersheds were within 3 km (1 mi) of the nearest study watersheds and were 4.2 and 5.1 ha (10.4 and 12.6 ac) in size (noted as Cabbage on figure 1). Native prairie was planted in 2004 in the two watersheds as described by Tomer et al (2010), providing a 100% prairie restoration reference comparison to the 12 agricultural watersheds for the years of 2010 and 2011. These prairie watersheds were not part of the original experimental design and were sampled only from 2010.…”

Section: Methodsmentioning

confidence: 99%

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Nutrient removal by prairie filter strips in agricultural landscapes

Zhou¹,

Helmers²,

Asbjornsen³

et al. 2014

Journal of Soil and Water Conservation

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Nitrogen (N) and phosphorus (P) from agricultural landscapes have been identified as primary sources of excess nutrients in aquatic systems. The main objective of this study was to evaluate the effectiveness of prairie filter strips (PFS) in removing nutrients from cropland runoff in 12 small watersheds in central Iowa. Four treatments with PFS of different spatial coverage and distribution (No-PFS, 10% PFS, 10% PFS with strips, and 20% PFS with strips) were arranged in a balanced incomplete block design across four blocks in 2007. A no-tillage two-year corn (Zea mays L.) -soybean (Glycine max [L.] Merr.) rotation was grown in row-cropped areas beginning in 2007. Runoff was monitored by H flumes, and runoff water samples were collected during the growing seasons to determine concentrations of nitrate-nitrogen (NO 3 -N), total nitrogen (TN) and total phosphorus (TP) through 2011. Overall, the presence of PFS reduced mean annual NO 3 -N, TN, and TP concentrations by 35%, 73%, and 82%, respectively, and reduced annual NO 3 -N, TN, and TP losses by 67%, 84%, and 90%, respectively. However, the amount and distribution of PFS had no significant impact on runoff and nutrient yields. The findings suggest that utilization of PFS at the footslope position of annual row crop systems provides an effective approach to reducing nutrient loss in runoff from small agricultural watersheds. Runoff was monitored by H flumes, and runoff water samples were collected during the growing seasons to determine concentrations of nitrate-nitrogen (NO 3 -N), total nitrogen (TN) and total phosphorus (TP) through 2011. Overall, the presence of PFS reduced mean annual NO 3 -N, TN, and TP concentrations by 35%, 73%, and 82%, respectively, and reduced annual NO 3 -N, TN, and TP losses by 67%, 84%, and 90%, respectively. However, the amount and distribution of PFS had no significant impact on runoff and nutrient yields. The findings suggest that utilization of PFS at the footslope position of annual row crop systems provides an effective approach to reducing nutrient loss in runoff from small agricultural watersheds.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Nutrient removal by prairie filter strips in agricultural landscapes

Zhou¹,

Helmers²,

Asbjornsen³

et al. 2014

Journal of Soil and Water Conservation

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“…Studies based on both modeling 64,65 and empirical measurements 66,67 suggest a nonlinear relationship between the amount of perennial cover and different hydrologic services, resulting in diminishing returns beyond a certain amount. Such nonlinear relationships have been demonstrated for sediment trapping efficiency 61,63,68,69 , retention of nitrogen (N), phosphorus (P) 68,70,71 and pesticides 72 , and runoff reduction 55,56 . Combined, these findings underscore the notion that relatively small amounts of perennial cover may produce significant ES benefits, while minimizing negative impacts on crop production (Fig.…”

Section: Hydrologic Regulation and Water Purificationmentioning

confidence: 98%

“…Possible approaches to developing perennial grain crops include using related perennial species to add genes into annual crops such as wheat, and domesticating existing perennial species, such as intermediate wheatgrass (Thinopyrum intermedium), Maximilian sunflower (Helianthus maximiliani) and Illinois bundleflower (Desmanthus illinoensis), through selection for higher seed production and desirable agronomic and quality factors. Important biological and technical challenges exist for both approaches, but these might be surmountable in much less time than the millennia that were required to domesticate wheat, maize, rice and other grains 71 . Perennial grain crops may have a lower yield potential than annuals due to trade-offs between seed productivity and longevity: resources that might be allocated to seeds may instead have to be allocated to non harvested perennating structures to maintain survival from year to year 275 .…”

Section: Grain Cropsmentioning

confidence: 99%

Targeting perennial vegetation in agricultural landscapes for enhancing ecosystem services

Asbjornsen

Hernández‐Santana

Liebman

et al. 2013

Renew. Agric. Food Syst.

235

168

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Over the past century, agricultural landscapes worldwide have increasingly been managed for the primary purpose of producing food, while other diverse ecosystem services potentially available from these landscapes have often been undervalued and diminished. The incorporation of relatively small amounts of perennial vegetation in strategic locations within agricultural landscapes dominated by annual crops-or perennialization-creates an opportunity for enhancing the provision of a wide range of goods and services to society, such as water purification, hydrologic regulation, pollination services, control of pest and pathogen populations, diverse food and fuel products, and greater resilience to climate change and extreme disturbances, while at the same time improving the sustainability of food production. This paper synthesizes the current scientific theory and evidence for the role of perennial plants in balancing conservation with agricultural production, focusing on the Midwestern USA as a model system, while also drawing comparisons with other climatically diverse regions of the world. Particular emphasis is given to identifying promising opportunities for advancement and critical gaps in our knowledge related to purposefully integrating perennial vegetation into agroecosystems as a management tool for maximizing multiple benefits to society. AbstractOver the past century, agricultural landscapes worldwide have increasingly been managed for the primary purpose of producing food, while other diverse ecosystem services potentially available from these landscapes have often been undervalued and diminished. The incorporation of relatively small amounts of perennial vegetation in strategic locations within agricultural landscapes dominated by annual crops-or perennialization-creates an opportunity for enhancing the provision of a wide range of goods and services to society, such as water purification, hydrologic regulation, pollination services, control of pest and pathogen populations, diverse food and fuel products, and greater resilience to climate change and extreme disturbances, while at the same time improving the sustainability of food production. This paper synthesizes the current scientific theory and evidence for the role of perennial plants in balancing conservation with agricultural production, focusing on the Midwestern USA as a model system, while also drawing comparisons with other climatically diverse regions of the world. Particular emphasis is given to identifying promising opportunities for advancement and critical gaps in our knowledge related to purposefully integrating perennial vegetation into agroecosystems as a management tool for maximizing multiple benefits to society.

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“…For example, though Farms B and E share the same production practices, Farm B reduces the amount of N entering its adjacent headwaters through enhanced on-farm ecosystem services (e.g., 90% removal due to riparian buffers, swales, holding ponds, hedgerows, etc. [28]), as compared to Farm E. Once the runoff N leaves a farm boundary and enters surface waters, the measurable impact drops rapidly due to dilution (i.e., a rapid increase in drainage area) and continues to fall due to both continued dilution and accumulated aquatic ecosystem services [29]. Again, while this aquatic ecosystem service could be assessed relative to some criteria at any scale, Figure 3 illustrates its assessment along the main branch, up to the watershed mouth.…”

Section: Ecosystem Servicesmentioning

confidence: 99%

A Scale-Explicit Framework for Conceptualizing the Environmental Impacts of Agricultural Land Use Changes

et al. 2014

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Demand for locally-produced food is growing in areas outside traditionally dominant agricultural regions due to concerns over food safety, quality, and sovereignty; rural livelihoods; and environmental integrity. Strategies for meeting this demand rely upon agricultural land use change, in various forms of either intensification or extensification (converting non-agricultural land, including native landforms, to agricultural use). The nature and extent of the impacts of these changes on non-food-provisioning ecosystem services are determined by a complex suite of scale-dependent interactions among farming practices, site-specific characteristics, and the ecosystem services under consideration. Ecosystem modeling strategies which honor such complexity are often impenetrable by non-experts, resulting in a prevalent conceptual gap between ecosystem sciences and the field of sustainable agriculture. Referencing heavily forested New England as an example, we present a conceptual framework designed to synthesize and convey understanding of the scale-and landscape-dependent nature of the relationship between agriculture and various ecosystem services. By accounting for the total impact of multiple disturbances across a landscape while considering the effects of scale, the framework is intended to stimulate and OPEN ACCESSSustainability 2014, 6 8433 support the collaborative efforts of land managers, scientists, citizen stakeholders, and policy makers as they address the challenges of expanding local agriculture.

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Perennial Filter Strips Reduce Nitrate Levels in Soil and Shallow Groundwater after Grassland‐to‐Cropland Conversion

Cited by 59 publications

References 44 publications

Nutrient removal by prairie filter strips in agricultural landscapes

Nutrient removal by prairie filter strips in agricultural landscapes

Targeting perennial vegetation in agricultural landscapes for enhancing ecosystem services

A Scale-Explicit Framework for Conceptualizing the Environmental Impacts of Agricultural Land Use Changes

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