|Uncertainty in simulating wheat yields under climate change|
Nature Climate Change 3 (9), 827-832, 2013
|Rising temperatures reduce global wheat production|
S Asseng, F Ewert, P Martre, RP Rötter, DB Lobell, D Cammarano, ...
Nature climate change 5 (2), 143, 2015
|How do various maize crop models vary in their responses to climate change factors?|
S Bassu, N Brisson, JL Durand, K Boote, J Lizaso, JW Jones, ...
Global change biology 20 (7), 2301-2320, 2014
|A network of terrestrial environmental observatories in Germany|
S Zacharias, H Bogena, L Samaniego, M Mauder, R Fuß, T Pütz, ...
Vadose Zone Journal 10 (3), 955-973, 2011
|Comparison of N2O emissions from soils at three temperate agricultural sites: simulations of year-round measurements by four models|
SE Frolking, AR Mosier, DS Ojima, C Li, WJ Parton, CS Potter, E Priesack, ...
Nutrient Cycling in Agroecosystems 52 (2-3), 77-105, 1998
|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
|Closed-form expression for the multi-modal unsaturated conductivity function|
E Priesack, W Durner
Vadose Zone Journal 5 (1), 121-124, 2006
|The plant's capacity in regulating resource demand|
R Matyssek, R Agerer, D Ernst, JC Munch, W Osswald, H Pretzsch, ...
Plant biology 7 (06), 560-580, 2005
|Modeling biomass growth, N-uptake and phenological development of potato crop|
S Gayler, E Wang, E Priesack, T Schaaf, FX Maidl
Geoderma 105 (3-4), 367-383, 2002
|Spatial variation of nitrate–N and related soil properties at the plot-scale|
R Stenger, E Priesack, F Beese
Geoderma 105 (3-4), 259-275, 2002
|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
|Expert-N-A Building Block System of Nitrogen Models as Resource for Advice, Research, Water Management and Policy|
T Engel, E Priesack
Integrated soil and sediment research: A basis for proper protection, 503-507, 1993
|Evaluating the ability of four crop models to predict different environmental impacts on spring wheat grown in open-top chambers|
C Biernath, S Gayler, S Bittner, C Klein, P Högy, A Fangmeier, E Priesack
European Journal of Agronomy 35 (2), 71-82, 2011
|Solute transport modeled with Green's functions with application to persistent solute sources|
FJ Leij, E Priesack, MG Schaap
Journal of Contaminant Hydrology 41 (1-2), 155-173, 2000
|Rates of net nitrogen mineralization in disturbed and undisturbed soils|
R Stenger, E Priesack, F Beese
Plant and Soil 171 (2), 323-332, 1995
|A one-dimensional model of water flow in soil-plant systems based on plant architecture|
M Janott, S Gayler, A Gessler, M Javaux, C Klier, E Priesack
Plant and soil 341 (1-2), 233-256, 2011
|A dynamical model of environmental effects on allocation to carbon-based secondary compounds in juvenile trees|
S Gayler, TEE Grams, W Heller, D Treutter, E Priesack
Annals of Botany 101 (8), 1089-1098, 2008
|The impact of crop growth sub-model choice on simulated water and nitrogen balances|
E Priesack, S Gayler, HP Hartmann
Nutrient Cycling in Agroecosystems 75 (1-3), 1-13, 2006
|The North-South divide! Organic wastes, or resources for nutrient management?|
KE Giller, G Cadisch, C Palm
Agronomie 22 (7-8), 703-709, 2002