Summary
Most fruit crop irrigation scheduling is performed on empirical basis, with very little or no awareness of the consequences on yields and on water use efficiency. The main objective of this project is to obtain a model for the estimation of stomatal conductance through sap flux measurement in Actinidia, allowing assessment of plant’s water status and correct management of irrigation, while optimizing fruit quality. This goal will be reached through the following specific objectives: (i) to adjust models for estimation of leaf stomatal conductance of kiwifruit trees from measurements of sap flux density and atmospheric vapor pressure deficit; (ii) to understand which irrigation level optimizes fruit quality and productivity; (iii) to develop precision irrigation protocols based on stomatal conductance estimation. This project will lead to innovative results as it will (i) provide a model to estimate leaf stomatal conductance on an isohydric, drought sensible crop (kiwifruit) with high hydraulic conductance, allowing to understand the hydraulic limitations and physiological responses of one of the most water requiring crops; (ii) improve understanding on how a different plant water status and physiological performance at source level affects fruit yield and quality, and; (iii) provide a tool to optimize irrigation scheduling of Actinidia, based on estimated leaf stomatal conductance. While reaching these scientific objectives, Dr. Fernandes will acquire: (i) research skills by leading the project and being involved in the preparation of further proposal; (ii) teaching skills, by holding seminars and tutoring Master’s students; and (iii) networking skills, by participating at several meeting national and international working groups as well as through a strong interaction with stakeholders. The exploitation of results will be maximized by foreseen open access results and a wide range of dissemination and communication tools adapted to different target groups.
Unfold all
/
Fold all
More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101066378 |
| Start date: | 15-03-2023 |
| End date: | 14-03-2025 |
| Total budget - Public funding: | - 172 750,00 Euro |
Cordis data
Original description
Most fruit crop irrigation scheduling is performed on empirical basis, with very little or no awareness of the consequences on yields and on water use efficiency. The main objective of this project is to obtain a model for the estimation of stomatal conductance through sap flux measurement in Actinidia, allowing assessment of plant’s water status and correct management of irrigation, while optimizing fruit quality. This goal will be reached through the following specific objectives: (i) to adjust models for estimation of leaf stomatal conductance of kiwifruit trees from measurements of sap flux density and atmospheric vapor pressure deficit; (ii) to understand which irrigation level optimizes fruit quality and productivity; (iii) to develop precision irrigation protocols based on stomatal conductance estimation. This project will lead to innovative results as it will (i) provide a model to estimate leaf stomatal conductance on an isohydric, drought sensible crop (kiwifruit) with high hydraulic conductance, allowing to understand the hydraulic limitations and physiological responses of one of the most water requiring crops; (ii) improve understanding on how a different plant water status and physiological performance at source level affects fruit yield and quality, and; (iii) provide a tool to optimize irrigation scheduling of Actinidia, based on estimated leaf stomatal conductance. While reaching these scientific objectives, Dr. Fernandes will acquire: (i) research skills by leading the project and being involved in the preparation of further proposal; (ii) teaching skills, by holding seminars and tutoring Master’s students; and (iii) networking skills, by participating at several meeting national and international working groups as well as through a strong interaction with stakeholders. The exploitation of results will be maximized by foreseen open access results and a wide range of dissemination and communication tools adapted to different target groups.Status
SIGNEDCall topic
HORIZON-MSCA-2021-PF-01-01Update Date
09-02-2023
Images
No images available.
Geographical location(s)
