Assessing long‐term impacts of cover crops on soil organic carbon in the central US Midwestern agroecosystems

Cover crops have been reported as one of the most effective practices to increase soil organic carbon (SOC) for agroecosystems. Impacts of cover crops on SOC change vary depending on soil properties, climate, and management practices, but it remains unclear how these control factors affect SOC benefits from cover crops, as well as which management practices can maximize SOC benefits. To address these questions, we used an advanced process‐based agroecosystem model, ecosys, to assess the impacts of winter cover cropping on SOC accumulation under different environmental and management conditions. We aimed to answer the following questions: (1) To what extent do cover crops benefit SOC accumulation, and how do SOC benefits from cover crops vary with different factors (i.e., initial soil properties, cover crop types, climate during the cover crop growth period, and cover crop planting and terminating time)? (2) How can we enhance SOC benefits from cover crops under different cover crop management options? Specifically, we first calibrated and validated the ecosys model at two long‐term field experiment sites with SOC measurements in Illinois. We then applied the ecosys model to six cover crop field experiment sites spanning across Illinois to assess the impacts of different factors on SOC accumulation. Our modeling results revealed the following findings: (1) Growing cover crops can bring SOC benefits by 0.33 ± 0.06 MgC ha−1 year−1 in six cover crop field experiment sites across Illinois, and the SOC benefits are species specific to legume and non‐legume cover crops. (2) Initial SOC stocks and clay contents had overall small influences on SOC benefits from cover crops. During the cover crop growth period (i.e., winter and spring in the US Midwest), high temperature increased SOC benefits from cover crops, while the impacts from larger precipitation on SOC benefits varied field by field. (3) The SOC benefits from cover crops can be maximized by optimizing cover crop management practices (e.g., selecting cover crop types and controlling cover crop growth period) for the US Midwestern maize–soybean rotation system. Finally, we discussed the economic and policy implications of adopting cover crops in the US Midwest, including that current economic incentives to grow cover crops may not be sufficient to cover costs. This study systematically assessed cover crop impacts for SOC change in the US Midwest context, while also demonstrating that the ecosys model, with rigorous validation using field experiment data, can be an effective tool to guide the adaptive management of cover crops and quantify SOC benefits from cover crops. The study thus provides practical tools and insights for practitioners and policy‐makers to design cover crop related government agricultural policies and incentive programs for farmers and agri‐food related industries.

[1]  K. Guan,et al.  How does uncertainty of soil organic carbon stock affect the calculation of carbon budgets and soil carbon credits for croplands in the U.S. Midwest? , 2023, Geoderma.

[2]  J. Kaye,et al.  Cover crop functional types differentially alter the content and composition of soil organic carbon in particulate and mineral‐associated fractions , 2022, Global change biology.

[3]  K. Guan,et al.  How to estimate soil organic carbon stocks of agricultural fields? perspectives using ex-ante evaluation , 2022, Geoderma.

[4]  J. Sanderman,et al.  Crediting agricultural soil carbon sequestration , 2022, Science.

[5]  Lisa A. Durso,et al.  Time in a bottle: Use of soil archives for understanding long‐term soil change , 2022, Soil Science Society of America Journal.

[6]  K. Guan,et al.  A roadmap toward scalably quantifying field-level agricultural carbon outcome , 2022 .

[7]  K. Guan,et al.  Assessing the impacts of cover crops on maize and soybean yield in the U.S. Midwestern agroecosystems , 2021, Field Crops Research.

[8]  C. Creech,et al.  Implications of cover crop planting and termination timing on rainfed maize production in semi-arid cropping systems , 2021 .

[9]  R. Grant,et al.  Quantifying carbon budget, crop yields and their responses to environmental variability using the ecosys model for U.S. Midwestern agroecosystems , 2021 .

[10]  K. Paustian,et al.  Management of cover crops in temperate climates influences soil organic carbon stocks: a meta-analysis. , 2020, Ecological applications : a publication of the Ecological Society of America.

[11]  M. van Kleunen,et al.  Effect of allelopathy on plant performance: a meta-analysis. , 2020, Ecology letters.

[12]  S. Archontoulis,et al.  Simulating winter rye cover crop production under alternative management in a corn‐soybean rotation , 2020, Agronomy Journal.

[13]  H. Tian,et al.  Can N2O emissions offset the benefits from soil organic carbon storage? , 2020, Global change biology.

[14]  James W. Jones,et al.  Towards a multiscale crop modelling framework for climate change adaptation assessment , 2020, Nature Plants.

[15]  M. Reiter,et al.  A meta-analysis of global cropland soil carbon changes due to cover cropping , 2020 .

[16]  Philip Smith,et al.  The role of soil carbon in natural climate solutions , 2020, Nature Sustainability.

[17]  R. Stewart,et al.  Quantifying cover crop effects on soil health and productivity , 2020, Data in brief.

[18]  K. Guan,et al.  Do cover crops benefit soil microbiome? A meta-analysis of current research , 2020 .

[19]  S. Everhart,et al.  Is allelopathy from winter cover crops affecting row crops? , 2020, Agricultural & Environmental Letters.

[20]  E. Nafziger,et al.  Agronomic and Environmental Assessment of Cover Crops Project Data , 2019 .

[21]  Matthias Kuhnert,et al.  How to measure, report and verify soil carbon change to realize the potential of soil carbon sequestration for atmospheric greenhouse gas removal , 2019, Global change biology.

[22]  M. Villamil,et al.  Cover crop rotations affect greenhouse gas emissions and crop production in Illinois, USA , 2019, Field Crops Research.

[23]  A. O'Geen,et al.  Deep soil inventories reveal that impacts of cover crops and compost on soil carbon sequestration differ in surface and subsurface soils , 2019, Global change biology.

[24]  Shizong Wang,et al.  Preparation, modification and environmental application of biochar: A review , 2019, Journal of Cleaner Production.

[25]  P. Jacinthe,et al.  Responses of soil carbon sequestration to climate‐smart agriculture practices: A meta‐analysis , 2019, Global change biology.

[26]  Pete Smith,et al.  A critical review of the impacts of cover crops on nitrogen leaching, net greenhouse gas balance and crop productivity , 2019, Global change biology.

[27]  D. Bastviken,et al.  2019 Refinement to the 2006 IPCC Guidelines for National Greenhouse Gas Inventories. Volume 4: Agriculture, Forestry and Other Land Use. Chapter 7: Wetlands , 2019 .

[28]  F. Miguez,et al.  Annual Net Returns to Cover Crops in Iowa , 2018, Journal of Applied Farm Economics.

[29]  R. Ceulemans,et al.  Below-ground carbon inputs contribute more than above-ground inputs to soil carbon accrual in a bioenergy poplar plantation , 2018, Plant and Soil.

[30]  J. Lavallee,et al.  Incorporation of shoot versus root-derived 13C and 15N into mineral-associated organic matter fractions: results of a soil slurry incubation with dual-labelled plant material , 2018, Biogeochemistry.

[31]  Marnik Vanclooster,et al.  Assessing cover crop management under actual and climate change conditions. , 2017, The Science of the total environment.

[32]  G. Hartman,et al.  Suppression of Soilborne Diseases of Soybean With Cover Crops. , 2017, Plant disease.

[33]  R. Alvarez,et al.  Cover crop effects on soils and subsequent crops in the pampas: A meta-analysis , 2017 .

[34]  M. Robertson,et al.  Data requirement for effective calibration of process-based crop models , 2017 .

[35]  J. Tyndall,et al.  The trouble with cover crops: Farmers’ experiences with overcoming barriers to adoption , 2017, Renewable Agriculture and Food Systems.

[36]  B. McConkey,et al.  Increased uncertainty in soil carbon stock measurement with spatial scale and sampling profile depth in world grasslands: A systematic analysis , 2017 .

[37]  W. K. Kellogg Cover crop root contributions to soil carbon in a no-till corn bioenergy cropping system , 2017 .

[38]  S. Ogle,et al.  Climate-smart soils , 2016, Nature.

[39]  K. Balkcom,et al.  Timing of Cover Crop Termination: Management Considerations for the Southeast , 2015 .

[40]  J. Lindquist,et al.  Cover Crops and Ecosystem Services: Insights from Studies in Temperate Soils , 2015 .

[41]  A. Barker,et al.  Monitoring, reporting and verifying emissions in the climate economy , 2015 .

[42]  Axel Don,et al.  Carbon sequestration in agricultural soils via cultivation of cover crops – A meta-analysis , 2015 .

[43]  M. Ha-Duong,et al.  Climate change 2014 - Mitigation of climate change , 2015 .

[44]  L. Lipper,et al.  Climate-smart agriculture for food security , 2014 .

[45]  M. Castellano,et al.  Do cover crops increase or decrease nitrous oxide emissions? A meta-analysis , 2014, Journal of Soil and Water Conservation.

[46]  Kenneth Ray Olson,et al.  Long-Term Effects of Cover Crops on Crop Yields, Soil Organic Carbon Stocks and Sequestration , 2014 .

[47]  A. S. Grandy,et al.  Does agricultural crop diversity enhance soil microbial biomass and organic matter dynamics? A meta-analysis. , 2014, Ecological applications : a publication of the Ecological Society of America.

[48]  L. Schulte,et al.  Soil Carbon Storage , 2012 .

[49]  Jeffrey W. White,et al.  Controlled Warming Effects on Wheat Growth and Yield: Field Measurements and Modeling , 2011 .

[50]  J. Poesen,et al.  Cover crops and their erosion-reducing effects during concentrated flow erosion , 2011 .

[51]  E. Nafziger,et al.  Soil Organic Carbon Trends Over 100 Years in the Morrow Plots , 2011 .

[52]  R. Miles,et al.  The Sanborn field experiment: implications for long-term soil organic carbon levels. , 2011 .

[53]  Kenneth Ray Olson,et al.  Cover Crop Effects on Crop Yields and Soil Organic Carbon Content , 2010 .

[54]  Lucy R. Hutyra,et al.  Modeling the carbon balance of Amazonian rain forests: resolving ecological controls on net ecosystem productivity , 2009 .

[55]  R. Omonode,et al.  Soil carbon dioxide and methane fluxes from long-term tillage systems in continuous corn and corn–soybean rotations , 2007 .

[56]  R. Lal,et al.  Carbon Sequestration , 2010 .

[57]  Y. Zhangb,et al.  Intercomparison of techniques to model water stress effects on CO 2 and energy exchange in temperate and boreal deciduous forests , 2006 .

[58]  V. Baligar,et al.  Role of Cover Crops in Improving Soil and Row Crop Productivity , 2005 .

[59]  R. Lal,et al.  Soil carbon dynamics in cropland and rangeland. , 2002, Environmental pollution.

[60]  I. Burke,et al.  REGIONAL PATTERNS OF DECOMPOSITION AND PRIMARY PRODUCTION RATES IN THE U.S. GREAT PLAINS , 2002 .

[61]  S. Wofsy,et al.  Carbon and energy exchange by a black spruce – moss ecosystem under changing climate: testing the mathematical model ecosys with data from the BOREAS experiment , 2001 .

[62]  R. F. Grant A review of the Canadian ecosystem model ecosys , 2001 .

[63]  Ji‐Hyung Park,et al.  Controls on the dynamics of dissolved organic matter in soils: a review. , 2000 .

[64]  T. Sinclair,et al.  Historical changes in harvest index and crop nitrogen accumulation , 1998 .

[65]  R. Grant Changes in Soil Organic Matter under Different Tillage and Rotation: Mathematical Modeling in ecosys , 1997 .

[66]  S. Aref,et al.  Long-Term Trends of Corn Yield and Soil Organic Matter in Different Crop Sequences and Soil Fertility Treatments on the Morrow Plots , 1997 .

[67]  W. K. George,et al.  University of Illinois at Urbana-Champain , 1997 .

[68]  R. Grant,et al.  Simulation of carbon and nitrogen transformations in soil: mineralization. , 1993 .

[69]  R. Grant,et al.  Simulation of carbon and nitrogen transformations in soil : microbial biomass and metabolic products , 1993 .