Abstract

The western basin of Lake Erie, the shallowest of the Laurentian Great Lakes in North America, is now plagued by harmful algal blooms annually due to nutrient discharges primarily from its basin. Water quality was impacted so significantly by toxic cyanobacteria in 2014 that the city of Toledo’s water supply was shut off, affecting hundreds of thousands of residents. A new agricultural land management approach, ‘wetlaculture (=wetland + agriculture)’, has a goal of reducing the need for fertilizer applications while preventing fluxes of nutrients to downstream aquatic ecosystems. A wetlaculture mesocosm experiment was set up on agricultural land near Defiance, Ohio, on the northwestern edge of the former ‘Great Black Swamp’. The mesocosms were randomly assigned to four hydrologic treatments involving two water depths (no standing water and ~10-cm of standing water) and two hydraulic loading rates (10 and 30 cm week−1). Nearby agricultural ditch water was pumped to provide weekly hydraulic loading rates to the mesocosms. During the two-year period, the net mass retention of phosphorus from the water was estimated to have averaged 1.0 g P m−2 in the wetland mesocosms with a higher hydraulic loading rate, while the highest estimated net nitrogen mass retention (average 22 g N m−2) was shown in the wetland mesocosms with 10 cm of standing water and higher hydraulic loading rate. Our finding suggests that hydrologic conditions, especially water level, contribute directly and indirectly to nutrient retention, partially through the quick response of the wetland vegetation community. This study provides valuable information for scaling up to restore significant areas of wetlaculture/wetlands in the former Great Black Swamp, strategically focused on reducing the nutrient loading to western Lake Erie from the Maumee River Basin.

Highlights

  • IntroductionOver the last few decades, significant expansion of agricultural land use has been widely recognized for leading to global and regional negative environmental impacts, especially reduced soil fertility and increased eutrophication of surface water systems [1,2,3]

  • The running time was based onon thethe water level of the ditch, which was proThe running time was based water level of drainage the drainage ditch, which was foundly impacted by local precipitation and and evapotranspiration

  • 2019, nearby ditch water was pumped into a storagetank tankand andflowed flowedinto intothe the28 wetland weekly, for foraatotal totalof of13

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Summary

Introduction

Over the last few decades, significant expansion of agricultural land use has been widely recognized for leading to global and regional negative environmental impacts, especially reduced soil fertility and increased eutrophication of surface water systems [1,2,3]. Phosphorus and nitrogen are the two main elements in fertilizer and are the two key limiting factors of harmful algal blooms [4]. Wetlands have long been considered as an effective way to remove nutrients from stormwater/runoff to protect downstream rivers, lakes, and groundwater [5,6,7]. The influence of regional seasonality and hydrologic conditions are still poorly understood for agricultural runoff treatment wetlands [8]

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