Summary
Leaf phenology, the study of the seasonal timing and drivers of budburst, leaf unfolding, maturation and senescence, is the starting point of land carbon (C) cycle models, driving C allocation between organs, and thus largely controlling C budget estimates. It is often cited as one of the largest uncertainties in future climate predictions. Despite centuries of research, the environmental control of leaf phenology is still not fully understood. State-of-the-art approaches empirically relate phenophases to macroclimatic air temperature, unable to capture conditions sensed by the tree (microclimate) or species-specific variability. This translates into models unable to accurately reproduce forest response to climate change. Understanding why trees grow or shed their leaves is thus key to assessing the resilience of forests.
This project proposes a new paradigm for exploring the biophysical and ecophysiological controls of leaf phenology across scales, based on a unified theory linking phenology to species strategy and the coordination of physiological processes in a limiting environment. Key innovations are: (1) new insight into the microclimatic control of phenology through unprecedented monitoring of the bud/leaf energy budget, (2) the identification of the key links between phenology and species strategy, (3) the quantification of the colimiting factors of leaf phenology across scales, accounting for environmental and physiological processes, and (4) the application of a new generation of models incorporating the biophysical and ecophysiological controls of phenology.
These insights are urgently needed to reduce uncertainties in C cycle estimates and to assess the response of forest to climate within the context of the IPCC. These innovations will unlock several domains to which phenology is central (forestry, agriculture) and open a realm of untapped research questions and applications that require robust forecasting of forest dynamics (drought, fire).
This project proposes a new paradigm for exploring the biophysical and ecophysiological controls of leaf phenology across scales, based on a unified theory linking phenology to species strategy and the coordination of physiological processes in a limiting environment. Key innovations are: (1) new insight into the microclimatic control of phenology through unprecedented monitoring of the bud/leaf energy budget, (2) the identification of the key links between phenology and species strategy, (3) the quantification of the colimiting factors of leaf phenology across scales, accounting for environmental and physiological processes, and (4) the application of a new generation of models incorporating the biophysical and ecophysiological controls of phenology.
These insights are urgently needed to reduce uncertainties in C cycle estimates and to assess the response of forest to climate within the context of the IPCC. These innovations will unlock several domains to which phenology is central (forestry, agriculture) and open a realm of untapped research questions and applications that require robust forecasting of forest dynamics (drought, fire).
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101117001 |
| Start date: | 01-07-2024 |
| End date: | 30-06-2029 |
| Total budget - Public funding: | 2 013 578,00 Euro - 2 013 578,00 Euro |
Cordis data
Original description
Leaf phenology, the study of the seasonal timing and drivers of budburst, leaf unfolding, maturation and senescence, is the starting point of land carbon (C) cycle models, driving C allocation between organs, and thus largely controlling C budget estimates. It is often cited as one of the largest uncertainties in future climate predictions. Despite centuries of research, the environmental control of leaf phenology is still not fully understood. State-of-the-art approaches empirically relate phenophases to macroclimatic air temperature, unable to capture conditions sensed by the tree (microclimate) or species-specific variability. This translates into models unable to accurately reproduce forest response to climate change. Understanding why trees grow or shed their leaves is thus key to assessing the resilience of forests.This project proposes a new paradigm for exploring the biophysical and ecophysiological controls of leaf phenology across scales, based on a unified theory linking phenology to species strategy and the coordination of physiological processes in a limiting environment. Key innovations are: (1) new insight into the microclimatic control of phenology through unprecedented monitoring of the bud/leaf energy budget, (2) the identification of the key links between phenology and species strategy, (3) the quantification of the colimiting factors of leaf phenology across scales, accounting for environmental and physiological processes, and (4) the application of a new generation of models incorporating the biophysical and ecophysiological controls of phenology.
These insights are urgently needed to reduce uncertainties in C cycle estimates and to assess the response of forest to climate within the context of the IPCC. These innovations will unlock several domains to which phenology is central (forestry, agriculture) and open a realm of untapped research questions and applications that require robust forecasting of forest dynamics (drought, fire).
Status
SIGNEDCall topic
ERC-2023-STGUpdate Date
03-10-2024
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