2024-03-29T04:46:45Zhttp://digital.csic.es/dspace-oai/requestoai:digital.csic.es:10261/637442018-09-11T08:47:15Zcom_10261_15com_10261_6col_10261_268
00925njm 22002777a 4500
dc
Fernández Luque, José Enrique
author
Díaz-Espejo, Antonio
author
D'Andria, R.
author
Sebastiani, Lorenzo
author
Tognetti, R.
author
2008
Data from Spanish and Italian olive orchards with different cultivars (>Manzanilla>, >Frantoio>, >Leccino>, >Razzola> and >Taggiasca>) growing in different environments (southern Spain; north, centre and south of Italy) were used to illustrate how models on water use and photosynthetic behaviour of the olive tree can be useful tools for choosing pruning intensity and canopy shape for optimum water use and carbon assimilation. Both original and published data on olive physiological behaviour were used to illustrate limitations of model performance due to both inadequate input variables and poor description of the processes involved. We observed differences on leaf water status between cultivars and locations, likely due to differences in soil characteristics related to soil matric potential and soil hydraulic conductivity. This suggests that the volumetric soil water content may not be the best variable for characterizing the soil water status when modelling, and highlights the importance of considering specific environmental conditions before extrapolating data from the literature to specific orchards. We evaluated the importance of considering the reduction in olive photosynthetic capacity under stress conditions, driven by a reduction in leaf mass per area and leaf nitrogen content. A modelling exercise was then made for a >Manzanilla> olive tree at the Spanish orchard, by combining a gas exchange model for olive leaves with a model able to simulate the spatial distribution of radiation and leaf-gas exchanges within the olive canopy as a function of canopy structure, canopy microclimate, and physical and physiological leaf properties. Simulated values for two different canopy shapes showed that a top-open spherical canopy, typical in the area, improved water use efficiency, as compared to a spherical canopy closed at the top. The model also showed the value of leaf area density that must be left after pruning for optimizing carbon assimilation relative to water consumption.
Plant Biosystems 142(1): 130-137 (2008)
http://hdl.handle.net/10261/63744
10.1080/11263500701872853
Potential and limitations of improving olive orchard design and management through modelling