Comparative analysis of hydrologic signatures in two agricultural watersheds in east-central Illinois: legacies of the past to inform the future

M A Yaeger,X Cai,G F Mcisaac,M Sivapalan

doi:10.5194/hess-17-4607-2013

M A Yaeger, X Cai + Show 2 more

Open Access

https://doi.org/10.5194/hess-17-4607-2013

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Abstract

Abstract. Historically, the central Midwestern US has undergone drastic anthropogenic land use change, having been transformed, in part through government policy, from a natural grassland system to an artificially drained agricultural system devoted to row cropping corn and soybeans. Current federal policies are again influencing land use in this region with increased corn acreage and new biomass crops proposed as part of an energy initiative emphasizing biofuels. To better address these present and future challenges it is helpful to understand whether and how the legacies of past changes have shaped the current response of the system. To this end, a comparative analysis of the hydrologic signatures in both spatial and time series data from two central Illinois watersheds was undertaken. The past history of these catchments is reflected in their current hydrologic responses, which are highly heterogeneous due to differences in geologic history, artificial drainage patterns, and reservoir operation, and manifest temporally, from annual to daily timescales, and spatially, both within and between the watersheds. These differences are also apparent from analysis of the summer low flows, where the more tile-drained watershed shows greater variability overall than does the more naturally drained one. In addition, precipitation in this region is also spatially heterogeneous even at small scales, and this, interacting with and filtering through the historical modifications to the system, increases the complexity of the problem of predicting the catchment response to future changes.

Highlights

The Renewable Fuel Standard (RFS), a provision of the US Energy Policy Act of 2005, mandated 7.5 billion gallons of renewable fuels by 2012, and was subsequently expanded to require 36 billion gallons by 2022
The differences in annual streamflow between the two watersheds can be explained in part by the spatial variability in precipitation described in Sect. 2.2 and which is shown in Fig. 5, as well as the catchment response to it
The storage in two large, main-stem flood control reservoirs in Kaskaskia is instrumental in reducing nitrate-N output from the watershed as well as reducing flow variability on controlled reaches, while the storage in smaller, municipal water supply reservoirs in Sangamon is diverted for human use, further reducing low flows and increasing the number of zeroflow days expected for the size of the drainage area

Summary

Introduction

The Renewable Fuel Standard (RFS), a provision of the US Energy Policy Act of 2005, mandated 7.5 billion gallons of renewable fuels by 2012, and was subsequently expanded to require 36 billion gallons by 2022 This mandate has created and increased the demand for biofuels, leading to an increasing demand for biofuel refinery feed-stocks. Perennial biomass crops such as Miscanthus giganteus and switchgrass, grown for cellulose-based ethanol production, have shown much promise Both field experiments (McIsaac et al, 2010; Smith et al, 2013) and watershed-scale modeling experiments (Ng et al, 2010) have shown that less nitrate is exported from Miscanthus compared to conventional

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