Modeling methane production from beef cattle using linear and nonlinear approaches [Erratum: 2009 May, v. 87, no. 5, p. 1849.]

Canada is committed to reducing its greenhouse gas emissions to 6% below 1990 amounts between 2008 and 2012, and methane is one of several greenhouse gases being targeted for reduction. Methane production from ruminants is one area in which the agriculture sector can contribute to reducing our globa...

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Veröffentlicht in:Journal of animal science 2009-04, Vol.87 (4), p.1334-1345
Hauptverfasser: Ellis, J.L, Kebreab, E, Odongo, N.E, Beauchemin, K, McGinn, S, Nkrumah, J.D, Moore, S.S, Christopherson, R, Murdoch, G.K, McBride, B.W, Okine, E.K, France, J
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Sprache:eng
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Zusammenfassung:Canada is committed to reducing its greenhouse gas emissions to 6% below 1990 amounts between 2008 and 2012, and methane is one of several greenhouse gases being targeted for reduction. Methane production from ruminants is one area in which the agriculture sector can contribute to reducing our global impact. Through mathematical modeling, we can further our understanding of factors that control methane production, improve national or global greenhouse gas inventories, and investigate mitigation strategies to reduce overall emissions. The purpose of this study was to compile an extensive database of methane production values measured on beef cattle, and to generate linear and nonlinear equations to predict methane production from variables that describe the diet. Extant methane prediction equations were also evaluated. The linear equation developed with the smallest root mean square prediction error (RMSPE, % observed mean) and residual variance (RV) was Eq. I: CH₄, MJ/d = 2.72 (±0.543) + [0.0937 (±0.0117) x ME intake, MJ/d] + [4.31 (±0.215) x Cellulose, kg/d] - [6.49 (±0.800) x Hemicellulose, kg/d] - [7.44 (±0.521) x Fat, kg/d] [RMSPE = 26.9%, with 94% of mean square prediction error (MSPE) being random error; RV = 1.13]. Equations based on ratios of one diet variable to another were also generated, and Eq. P, CH₄, MJ/d = 2.50 (±0.649) - [0.367 (±0.0191) x (Starch:ADF)] + [0.766 (±0.116) x DMI, kg/d], resulted in the smallest RMSPE values among these equations (RMSPE = 28.6%, with 93.6% of MSPE from random error; RV = 1.35). Among the nonlinear equations developed, Eq. W, CH₄, MJ/d = 10.8 (±1.45) x (1 - e[⁻⁰.¹⁴¹ ⁽±⁰.⁰³⁸¹⁾ x DMI, kg/d]), performed well (RMSPE = 29.0%, with 93.6% of MSPE from random error; RV = 3.06), as did Eq. W₃, CH₄, MJ/d = 10.8 (±1.45) x [1 - e{⁻ [⁻⁰.⁰³⁴ x ⁽NFC/NDF⁾ ⁺ ⁰.²²⁸] x DMI, kg/d}] (RMSPE = 28.0%, with 95% of MSPE from random error). Extant equations from a previous publication by the authors performed comparably with, if not better than in some cases, the newly developed equations. Equation selection by users should be based on RV and RMSPE analysis, input variables available to the user, and the diet fed, because the equation selected must account for divergence from a "normal" diet (e.g., high-concentrate diets, high-fat diets).
ISSN:0021-8812
1525-3163
DOI:10.2527/jas.2007-0725