New Representation of Plant Hydraulics Improves the Estimates of Transpiration in Land Surface Model

Li, Hongmei; Lu, Xingjie; Wei, Zhongwang; Zhu, Shuhui; Wei, Nan; Zhang, Shupeng; Yuan, Hua; Shangguan, Wei; Liu, Shaofeng; Zhang, Shulei; Huang, Jianfeng; Dai, Yongjiu

doi:10.3390/f12060722

Cited by 6 publications

(6 citation statements)

References 57 publications

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“…The present study further showed that the global fire count increment induced by PHS functions could be attributed to the elevated ecosystem water loss via plant transpiration and the resultant drier environment from the global perspective (Figure 8). Consistent with our results, the PHS configuration has been proven to increase plant transpiration at 81 FLUXNET sites across the globe [20] and over four different climatic subregions of China [21]. The PHS configuration uses water stress on leaf water potential to restrict transpiration; stress on transpiration can be induced by decreasing atmospheric moisture (e.g., increasing vapor pressure deficit) and soil water supply, and the latter was also regulated by root hydraulic redistribution (HR) processes [19].…”

Section: Discussionsupporting

confidence: 83%

“…It is worth mentioning that the PHS configuration in CLM5 allows for hydraulic redistribution (HR) and compensatory root water uptake. Previous research has confirmed that the incorporation of PHS configuration into CLM5 improved the estimates of ecosystem water and carbon fluxes [19][20][21]. Moreover, the PHS-incorporated CLM5 model could well reproduce the global wildfire carbon emission derived from the satellite products [22], and it has advantages against other LSMs, because the CLM5 uniquely considered the seasonality of crop fires and simulated the burning of plant tissue and litter from peat fires and the drought-linked tropical deforestation and degradation fire [23].…”

Section: Introductionmentioning

confidence: 82%

“…Previous land surface models, including the earlier versions of CLM, roughly related a metric of soil moisture to transpiration and neglected the real plant hydraulic functions [18,24]. More mechanistic representations of stresses and vegetation water use dynamics, i.e., the plant hydraulic stress (PHS) configuration, have been incorporated in the CLM5 and been suggested to improve the ecosystem water fluxes estimation [19][20][21]. Plant hydraulic stress (PHS) configuration is switched on by default and can also be turned off in CLM5.…”

Section: Plant Hydraulic Stress Configurationmentioning

confidence: 99%

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Elevated Wildfire and Ecosystem Carbon Loss Risks Due to Plant Hydraulic Stress Functions: A Global Modeling Perspective

Zhang

et al. 2022

Fire

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Wildfire risks are increasing due to the atmospheric and vegetation aridity under global warming. Plant hydraulic stress (PHS) functions regulate water transport along the soil–plant–atmosphere continuum under water stress conditions, which probably results in shifts in ecosystem wildfire regimes. Currently, how the PHS functions affect wildfire occurrence and subsequently the ecosystem carbon cycle via carbon loss at a global scale remains unclear. Here, we conducted global simulations during 1850–2010 using Community Land Model version 5 with and without the PHS configuration and quantified the PHS-induced changes. From the global perspective, the PHS functions increased plant transpiration, induced hydraulic redistribution (HR) of soil water by root, and decreased soil moisture; then, the functions increased fire occurrence (count), fire induced carbon loss, and ecosystem net primary productivity by 72%, 49%, and 15%, respectively. Spatially, the PHS functions greatly promoted fire occurrence and the consequent carbon loss in circumboreal forests and tropical savannas; whereas, the fire occurrence was limitedly affected or even decreased in equatorial rainforests. The strong downward HR process in the humid rainforests transported rainwater into deep soil layers, and strict stomatal regulation of the tropical trees restricted transpiration increment under atmospheric aridity, both of which helped to buffer the rainforests against drought and thus decreased fire risk. In contrast, dry savannas showed substantial upward HR, which increased water loss via soil evaporation and transpiration of the grasses with shallow roots. The tree–grass competition for limited soil moisture in the savannas benefited soil evaporation, which could aggravate plant hydraulic failure and increase wildfire risk.

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Section: Discussionsupporting

confidence: 83%

Section: Introductionmentioning

confidence: 82%

Section: Plant Hydraulic Stress Configurationmentioning

confidence: 99%

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Elevated Wildfire and Ecosystem Carbon Loss Risks Due to Plant Hydraulic Stress Functions: A Global Modeling Perspective

Zhang

et al. 2022

Fire

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“…A natural application for our model framework is its incorporation into land‐surface models. So far, the incorporation of plant hydraulics into land‐surface models has been used to investigate the feedback between climate and vegetation in terms of water cycle during non‐stressed conditions and drought, yet mechanistic plant responses to excessive soil water content are still lacking in these models (Li et al, 2021 ; Nguyen et al, 2020 ). With climate change expected to enhance surface evaporation and atmospheric vapor accumulation, the intensity and duration of droughts as well as the chances of flooding are both increased, underlining the demand for a framework capable of integrating both drought and flooding responses of plants (Trenberth, 2011 ).…”

Section: Discussion Concluding Remarks and Outlookmentioning

confidence: 99%

Parallels between drought and flooding: An integrated framework for plant eco‐physiological responses to water stress

Chen

Tusscher

Sasidharan

et al. 2023

Plant Enviro Interactions

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Drought and flooding occur at opposite ends of the soil moisture spectrum yet their resulting stress responses in plants share many similarities. Drought limits root water uptake to which plants respond with stomatal closure and reduced leaf gas exchange. Flooding limits root metabolism due to soil oxygen deficiency, which also limits root water uptake and leaf gas exchange. As drought and flooding can occur consecutively in the same system and resulting plant stress responses share similar mechanisms, a single theoretical framework that integrates plant responses over a continuum of soil water conditions from drought to flooding is attractive. Based on a review of recent literature, we integrated the main plant eco‐physiological mechanisms in a single theoretical framework with a focus on plant water transport, plant oxygen dynamics, and leaf gas exchange. We used theory from the soil–plant–atmosphere continuum modeling as “backbone” for our framework, and subsequently incorporated interactions between processes that regulate plant water and oxygen status, abscisic acid and ethylene levels, and the resulting acclimation strategies in response to drought, waterlogging, and complete submergence. Our theoretical framework provides a basis for the development of mathematical models to describe plant responses to the soil moisture continuum from drought to flooding.

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“…A natural application for our model framework is its incorporation into land-surface models. So far, the incorporation of plant hydraulics into land-surface models has been used to investigate the feedback between climate and vegetation in terms of water cycle during non-stressed conditions and drought, yet mechanistic plant responses to excessive soil water content are still lacking in these models (Li et al, 2021;Nguyen et al, 2020). With climate change expected to enhance surface evaporation and atmospheric vapor accumulation, the intensity and duration of droughts as well as the chances of flooding are both increased, underlining the demand for a framework capable of integrating both drought and flooding responses of plants (Trenberth, 2011).…”

Section: Discussion and Concluding Remarksmentioning

confidence: 99%

Parallels between drought and flooding: an integrated framework for plant eco-physiological responses to water stress

Chen

Tusscher

Sasidharan

et al. 2022

Preprint

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Drought and flooding occur at opposite ends of the soil moisture spectrum yet resulting stress responses that occur in plants share many similarities. Drought limits root water uptake to which plants respond with stomatal closure and reduced leaf gas exchange. Flooding limits root metabolism due to soil anoxia, which also limits root water uptake and leaf gas exchange. As drought and flooding can occur consecutively in the same system and resulting plant stress responses share similar mechanisms, a single theoretical framework that integrates plant responses over a continuum of soil water conditions from drought to flooding is attractive. Based on a review of recent literature, we integrated the main plant eco-physiological mechanisms in a single theoretical model with a focus on plant water transport, plant oxygen dynamics, and leaf gas exchange. We used the Soil-Plant-Atmosphere-Continuum model as “backbone” for our theoretical framework development, and subsequently incorporated interactions between processes that regulate plant water and oxygen status, levels of abscisic acid and ethylene hormones and resulting acclimation strategies in response to drought, waterlogging, and complete submergence. Our theoretical framework provides a basis for the development of mathematical models to describe plant responses to the soil moisture continuum from drought to flooding.

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New Representation of Plant Hydraulics Improves the Estimates of Transpiration in Land Surface Model

Cited by 6 publications

References 57 publications

Elevated Wildfire and Ecosystem Carbon Loss Risks Due to Plant Hydraulic Stress Functions: A Global Modeling Perspective

Elevated Wildfire and Ecosystem Carbon Loss Risks Due to Plant Hydraulic Stress Functions: A Global Modeling Perspective

Parallels between drought and flooding: An integrated framework for plant eco‐physiological responses to water stress

Parallels between drought and flooding: an integrated framework for plant eco-physiological responses to water stress

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