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This article in AJ

  1. Vol. 103 No. 1, p. 234-246
     
    Received: May 2, 2010
    Published: Jan, 2011


    * Corresponding author(s): hero.gollany@ars.usda.gov
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doi:10.2134/agronj2010.0203s

Predicting Agricultural Management Influence on Long-Term Soil Organic Carbon Dynamics: Implications for Biofuel Production

  1. H. T. Gollany *a,
  2. R. W. Rickmana,
  3. Y. Liangb,
  4. S. L. Albrechta,
  5. S. Machadoc and
  6. S. Kangd
  1. a USDA-ARS, Columbia Plateau Conservation Research Center, P.O. Box. 370, Pendleton, OR 97801
    b Dep. of Biological & Agricultural Engineering, Cooperative Extension Service, Univ. of Arkansas, Fayetteville, AR 72701-1201
    c Oregon State Univ., Columbia Basin Agricultural Research Center, Pendleton, OR 97801
    d Environmental Science Division, Oak Ridge National Lab., P.O. Box 2008, Oak Ridge, TN 37831-6290

Abstract

Long-term field experiments (LTE) are ideal for predicting the influence of agricultural management on soil organic carbon (SOC) dynamics and examining biofuel crop residue removal policy questions. Our objectives were (i) to simulate SOC dynamics in LTE soils under various climates, crop rotations, fertilizer or organic amendments, and crop residue managements using the CQESTR model and (ii) to predict the potential of no-tillage (NT) management to maintain SOC stocks while removing crop residue. Classical LTEs at Champaign, IL (1876), Columbia, MO (1888), Lethbridge, AB (1911), Breton, AB (1930), and Pendleton, OR (1931) were selected for their documented history of management practice and periodic soil organic matter (SOM) measurements. Management practices ranged from monoculture to 2- or 3-yr crop rotations, manure, no fertilizer or fertilizer additions, and crop residue returned, burned, or harvested. Measured and CQESTR predicted SOC stocks under diverse agronomic practices, mean annual temperature (2.1–19°C), precipitation (402–973 mm), and SOC (5.89−33.58 g SOC kg−1) at the LTE sites were significantly related (r 2 = 0.94, n = 186, P < 0.0001) with a slope not significantly different than 1. The simulation results indicated that the quantities of crop residue that can be sustainably harvested without jeopardizing SOC stocks were influenced by initial SOC stocks, crop rotation intensity, tillage practices, crop yield, and climate. Manure or a cover crop/intensified crop rotation under NT are options to mitigate loss of crop residue C, as using fertilizer alone is insufficient to overcome residue removal impact on SOC stocks.

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Copyright © 2011. American Society of AgronomyCopyright © 2011 by the American Society of Agronomy