Final published version
Research output: Contribution to Journal/Magazine › Journal article › peer-review
Crop productivity and the global livestock sector : implications for land use change and greenhouse gas emissions. / Havlík, Petr; Valin, Hugo; Mosnier, Aline et al.
In: American Journal of Agricultural Economics, Vol. 95, No. 2, 01.2013, p. 442-448.Research output: Contribution to Journal/Magazine › Journal article › peer-review
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TY - JOUR
T1 - Crop productivity and the global livestock sector
T2 - implications for land use change and greenhouse gas emissions
AU - Havlík, Petr
AU - Valin, Hugo
AU - Mosnier, Aline
AU - Obersteiner, Michael
AU - Baker, Justin S.
AU - Herrero, Mario
AU - Rufino, Mariana C.
AU - Schmid, Erwin
PY - 2013/1
Y1 - 2013/1
N2 - The livestock sector accounts for 30% of global land area and is a major driver of land use change. The price reductions generated by crop yield increases should, ceteris paribus, encourage farmers to replace some of the grass in ruminant rations with crops. This would lead to land sparing and related carbon dioxide emission reductions in regions where the feed productivity per unit of area is higher for cropland than for grassland. Six land cover types are distinguished in GLOBIOM: cropland, grassland, short rotation tree plantations, managed forest, unmanaged forest and other natural vegetation. Depending on the relative profitability of the individual activities, and on the inertia constraints, the model can switch from one land cover type to another. Comprehensive greenhouse gas accounting for agriculture and land use change is implemented in the model. Crop yield development will play a critical role in future land use dynamics. Indeed, it will determine the requirements for additional cropland, and also have a strong impact on grassland expansion.
AB - The livestock sector accounts for 30% of global land area and is a major driver of land use change. The price reductions generated by crop yield increases should, ceteris paribus, encourage farmers to replace some of the grass in ruminant rations with crops. This would lead to land sparing and related carbon dioxide emission reductions in regions where the feed productivity per unit of area is higher for cropland than for grassland. Six land cover types are distinguished in GLOBIOM: cropland, grassland, short rotation tree plantations, managed forest, unmanaged forest and other natural vegetation. Depending on the relative profitability of the individual activities, and on the inertia constraints, the model can switch from one land cover type to another. Comprehensive greenhouse gas accounting for agriculture and land use change is implemented in the model. Crop yield development will play a critical role in future land use dynamics. Indeed, it will determine the requirements for additional cropland, and also have a strong impact on grassland expansion.
U2 - 10.1093/ajae/aas085
DO - 10.1093/ajae/aas085
M3 - Journal article
AN - SCOPUS:84872721565
VL - 95
SP - 442
EP - 448
JO - American Journal of Agricultural Economics
JF - American Journal of Agricultural Economics
SN - 0002-9092
IS - 2
ER -