L. A. Lemordant scite author profile

SignificancePredicting how increasing atmospheric CO2 will affect the hydrologic cycle is of utmost importance for a wide range of applications. It is typically thought that future dryness will depend on precipitation changes, i.e., change in water supply, and changes in evaporative demand due to either increased radiation or temperature. Opposite to this viewpoint, using Earth system models, we show that changes in key water-stress variables will be strongly modified by vegetation physiological effects in response to increased [CO2] at the leaf level. These results emphasize that the continental carbon and water cycles have to be studied as an interconnected system.

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Modification of land‐atmosphere interactions by CO₂ effects: Implications for summer dryness and heat wave amplitude

Lemordant

Gentine

Stéfanon

et al. 2016

Geophysical Research Letters

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Plant stomata couple the energy, water, and carbon cycles. We use the framework of Regional Climate Modeling to simulate the 2003 European heat wave and assess how higher levels of surface CO2 may affect such an extreme event through land‐atmosphere interactions. Increased CO2 modifies the seasonality of the water cycle through stomatal regulation and increased leaf area. As a result, the water saved during the growing season through higher water use efficiency mitigates summer dryness and the heat wave impact. Land‐atmosphere interactions and CO2 fertilization together synergistically contribute to increased summer transpiration. This, in turn, alters the surface energy budget and decreases sensible heat flux, mitigating air temperature rise. Accurate representation of the response to higher CO2 levels and of the coupling between the carbon and water cycles is therefore critical to forecasting seasonal climate, water cycle dynamics, and to enhance the accuracy of extreme event prediction under future climate.

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Vegetation Response to Rising CO₂ Impacts Extreme Temperatures

Lemordant

Gentine

2019

Geophysical Research Letters

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Extreme temperatures are responsible for damages to society and ecosystems. There is evidence that severe episodes of extreme heat have been occurring more frequently and more severely in recent periods. Driven primarily by oceanic and atmospheric effects as well as land‐climate feedbacks, those extreme events are expected to increase with climate change. Vegetation, which regulates the energy, water, and carbon cycles, is a key player of land‐atmosphere interactions that has been proven to be determinant in recent extreme events. Using an ensemble of Earth System Models simulations, we show that physiological effects globally increase the annual daily maximum temperature (Txx) with rising [CO2], accounting globally for around 13% of the full Txx trend. Due to physiological effects, Txx can reinforce (e.g., central Europe) or reduce (e.g., central North America) the mean temperature increase.

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Growth and physiology of a dominant understory shrub, Hamamelis virginiana, following canopy disturbance in a temperate hardwood forest

et al. 2017

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As global climatic changes increase plant susceptibility to large-scale disturbances such as drought and pathogens, understory responses to these disturbances will become increasingly important to long-term forest dynamics. To better understand understory responses to canopy disturbance, we measured changes in the growth and physiology of the dominant understory shrub, American witch-hazel (Hamamelis virginiana L.), in response to girdling of canopy oaks in a temperate hardwood forest of the northeastern United States. Changes in the growth and physiology of H. virginiana may be important to the regeneration of northeastern temperate forests, as this common shrub largely shapes the microenvironment for seedlings on the forest floor where it occurs. Canopy disturbance by girdling resulted in significant increases in light and soil nitrogen availability. In response to these environmental changes, basal-area growth of H. virginiana increased by an average 334%. This growth increase corresponded to significant increases in foliar nitrogen, respiration, and leaf chlorophyll and carotenoid concentrations. These findings indicate improved environmental conditions and increased growth for this understory shrub following the loss of dominant canopy trees. This study suggests that following large-scale canopy disturbance, H. virginiana and shrubs like it may play an important role in competing for soil N and shading seedlings of regenerating canopy species.

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Interactions between Vegetation and Water Cycle In the Context of Rising Atmospheric Carbon Dioxide Concentration: Processes and Impacts on Extreme Temperature

Lemordant¹

2019

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L. A. Lemordant

Critical impact of vegetation physiology on the continental hydrologic cycle in response to increasing CO ₂

Modification of land‐atmosphere interactions by CO₂ effects: Implications for summer dryness and heat wave amplitude

Vegetation Response to Rising CO₂ Impacts Extreme Temperatures

Growth and physiology of a dominant understory shrub, Hamamelis virginiana, following canopy disturbance in a temperate hardwood forest

Interactions between Vegetation and Water Cycle In the Context of Rising Atmospheric Carbon Dioxide Concentration: Processes and Impacts on Extreme Temperature

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L. A. Lemordant

Critical impact of vegetation physiology on the continental hydrologic cycle in response to increasing CO 2

Modification of land‐atmosphere interactions by CO2 effects: Implications for summer dryness and heat wave amplitude

Vegetation Response to Rising CO2 Impacts Extreme Temperatures

Growth and physiology of a dominant understory shrub, Hamamelis virginiana, following canopy disturbance in a temperate hardwood forest

Interactions between Vegetation and Water Cycle In the Context of Rising Atmospheric Carbon Dioxide Concentration: Processes and Impacts on Extreme Temperature

Contact Info

Product

Resources

About

Critical impact of vegetation physiology on the continental hydrologic cycle in response to increasing CO ₂

Modification of land‐atmosphere interactions by CO₂ effects: Implications for summer dryness and heat wave amplitude

Vegetation Response to Rising CO₂ Impacts Extreme Temperatures