Incorporating Cultivar-Specific Stomatal Traits Into Stomatal Conductance Models Improves The Estimation Of Evapotranspiration Enhancing Greenhouse Climate Management

The effect of considering cultivar differences in stomatal conductance (g(s)) on relative air humidity (RH)-related energy demand was addressed. We conducted six experiments in order to study the variation in evapotranspiration (ETc) of six pot rose cultivars, investigate the underlying processes and parameterise a g(s)-based ETc model. Several levels of crop ETc were realised by adjusting the growth environment. The commonly applied Ball-Woodrow-Berry g(s)-sub-model (BWB-model) in ETc models was validated under greenhouse conditions, and showed a close agreement between simulated and measured ETc. The validated model was incorporated into a greenhouse simulator. A scenario simulation study showed that selecting low-g(s) cultivars reduces energy demand (<= 5.75%), depending on the RH set point. However, the BWB-model showed poor prediction quality at RH lower than 60% and a good fit at higher RH. Therefore, an attempt was made to improve model prediction: the in situ-obtained data were employed to adapt and extend either the BWB-model, or the Liu-extension with substrate water potential (Psi; BWB-Liu-model). Both models were extended with stomatal density (D-s) or pore area. Although the modified BWB-Liu-model (considering D-s) allowed higher accuracy (R-2 = 0.59), as compared to the basic version (R-2 = 0.31), the typical lack of Psi prediction in greenhouse models may be problematic for implementation into real-time climate control. The current study lays the basis for the development of cultivar specific cultivation strategies as well as improving the g(s) sub-model for dynamic climate conditions under low RH using model-based control systems. (C) 2021 The Author( s). Published by Elsevier Ltd on behalf of IAgrE.