|Rising temperatures reduce global wheat production|
S Asseng, F Ewert, P Martre, RP Rötter, DB Lobell, D Cammarano, ...
Nature climate change 5 (2), 143-147, 2015
|CropSyst, a cropping systems simulation model|
CO Stöckle, M Donatelli, R Nelson
European journal of agronomy 18 (3-4), 289-307, 2003
|Uncertainty in simulating wheat yields under climate change|
S Asseng, F Ewert, C Rosenzweig, JW Jones, JL Hatfield, AC Ruane, ...
Nature climate change 3 (9), 827-832, 2013
|CropSyst, a cropping systems simulation model: water/nitrogen budgets and crop yield|
CO Stockle, SA Martin, GS Campbell
Agricultural systems 46 (3), 335-359, 1994
|Effects of climate change and elevated CO2 on cropping systems: model predictions at two Italian locations|
FN Tubiello, M Donatelli, C Rosenzweig, CO Stockle
European Journal of Agronomy 13 (2-3), 179-189, 2000
|Climate change and agriculture in the United States: Effects and adaptation|
C Walthall, C Anderson, E Takle, L Baumgard, L Wright-Morton
|Multimodel ensembles of wheat growth: many models are better than one|
P Martre, D Wallach, S Asseng, F Ewert, JW Jones, RP Rötter, KJ Boote, ...
Global change biology 21 (2), 911-925, 2015
|Similar estimates of temperature impacts on global wheat yield by three independent methods|
B Liu, S Asseng, C Müller, F Ewert, J Elliott, DB Lobell, P Martre, ...
Nature Climate Change 6 (12), 1130-1136, 2016
|Estimating water erosion and sediment yield with GIS, RUSLE, and SEDD|
C Fernandez, JQ Wu, DK McCool, CO Stöckle
Journal of soil and Water Conservation 58 (3), 128-136, 2003
|Assessment of AquaCrop, CropSyst, and WOFOST models in the simulation of sunflower growth under different water regimes|
M Todorovic, R Albrizio, L Zivotic, MTA Saab, C Stöckle, P Steduto
Agronomy Journal 101 (3), 509-521, 2009
|Climate change impact and adaptation for wheat protein|
S Asseng, P Martre, A Maiorano, RP Rötter, GJ O’Leary, GJ Fitzgerald, ...
Global change biology 25 (1), 155-173, 2019
|A method for estimating the direct and climatic effects of rising atmospheric carbon dioxide on growth and yield of crops: Part I—Modification of the EPIC model for climate …|
CO Stockle, JR Williams, NJ Rosenberg, CA Jones
Agricultural systems 38 (3), 225-238, 1992
|The uncertainty of crop yield projections is reduced by improved temperature response functions|
E Wang, P Martre, Z Zhao, F Ewert, A Maiorano, RP Rötter, BA Kimball, ...
Nature plants 3 (8), 1-13, 2017
|Response of wheat growth, grain yield and water use to elevated CO2 under a Free‐Air CO2 Enrichment (FACE) experiment and modelling in a semi‐arid …|
GJ O'Leary, B Christy, J Nuttall, N Huth, D Cammarano, C Stöckle, ...
Global change biology 21 (7), 2670-2686, 2015
|Variability in crop radiation-use efficiency associated with vapor-pressure deficit|
CO Stockle, JR Kiniry
Field Crops Research 25 (3-4), 171-181, 1990
|A framework for evaluating the sustainability of agricultural production systems|
CO Stockle, RI Papendick, KE Saxton, GS Campbell, FK Van Evert
American journal of alternative agriculture 9 (1-2), 45-50, 1994
|Variability of barley radiation‐use efficiency|
AR Kemanian, CO Stöckle, DR Huggins
Crop science 44 (5), 1662-1672, 2004
|Climate change impacts on water management and irrigated agriculture in the Yakima River Basin, Washington, USA|
JA Vano, MJ Scott, N Voisin, CO Stöckle, AF Hamlet, KEB Mickelson, ...
Climatic Change 102, 287-317, 2010
|Predicting maize phenology: intercomparison of functions for developmental response to temperature|
S Kumudini, FH Andrade, KJ Boote, GA Brown, KA Dzotsi, GO Edmeades, ...
Agronomy Journal 106 (6), 2087-2097, 2014
|Evaluation of CropSyst for cropping systems at two locations of northern and southern Italy|
M Donatelli, CO Stöckle, E Ceotto, M Rinaldi
European Journal of Agronomy 6 (1-2), 35-45, 1997