Responses of Tree Growth and Intrinsic Water Use Efficiency to Environmental Factors in Central and Northern China in the Context of Global Warming

Ren, Mindong; Liu, Yu; Li, Qiang; Song, Huiming; Cai, Qiufang; Sun, Changfeng

doi:10.3390/f13081209

Cited by 3 publications

(4 citation statements)

References 55 publications

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“…In the study area, the intrinsic WUE was significantly negatively correlated with RH (R 2 = 0.02, p < 0.01, Figure 3 h), which was also been found in some previous studies [ 22 , 50 ]. The increase in RH relieves the water stress in plants, which promotes an increase in stomatal conductance.…”

Section: Discussionsupporting

confidence: 88%

“…The range of intrinsic WUE was from 8.61 to 123.39 μmol mol −1 with an average value of 60.66 μmol mol −1 ( Figure 1 b), which was lower than the result from global, arid and semiarid climate regions [ 49 , 50 ]. A previous study showed that the amount of water loss by plants often exceeds the amount of carbon accumulation by three orders of magnitude for terrestrial plants [ 14 ].…”

Section: Discussionmentioning

confidence: 66%

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Effects of Geographical and Climatic Factors on the Intrinsic Water Use Efficiency of Tropical Plants: Evidence from Leaf 13C

Lin

Wang

et al. 2023

Plants

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Understanding the water use efficiency (WUE) and adaptation strategies of plants in high-temperature and rainy areas is essential under global climate change. The leaf carbon content (LCC) and intrinsic WUE of 424 plant samples (from 312 plant species) on Hainan Island were measured to examine their relationship with geographical and climatic factors in herbs, trees, vines and ferns. The LCC ranged from 306.30 to 559.20 mg g−1, with an average of 418.85 mg g−1, and decreased with increasing mean annual temperature (MAT). The range of intrinsic WUE was 8.61 to 123.39 μmol mol−1 with an average value of 60.66 μmol mol−1. The intrinsic WUE decreased with increasing altitude and relative humidity (RH) and wind speed (WS), but increased with increasing latitude, MAT and rainy season temperature (RST), indicating that geographical and climatic factors affect the intrinsic WUE. Stepwise regression suggested that in tropical regions with high temperature and humidity, the change in plant intrinsic WUE was mainly driven by WS. In addition, the main factors affecting the intrinsic WUE of different plant functional types of plants are unique, implying that plants of different plant functional types have distinctive adaptive strategies to environmental change. The present study may provide an insight in water management in tropical rainforest.

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Section: Discussionsupporting

confidence: 88%

Section: Discussionmentioning

confidence: 66%

Effects of Geographical and Climatic Factors on the Intrinsic Water Use Efficiency of Tropical Plants: Evidence from Leaf 13C

Lin

Wang

et al. 2023

Plants

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“…On the other hand, the increased water use efficiency could indirectly lead to increases in ecosystem leaf index (Y. Zhang et al, 2022). Based on Ren et al's (2022) study of CO 2 and intrinsic water use efficiency (iWUE) within a forest ecosystem on the LP, there is a significant and continuous upward trend in water use efficiency spanning the past three centuries. The primary driver of this long‐term change in water use efficiency is the increasing concentration of atmospheric CO 2 .…”

Section: Discussionmentioning

confidence: 99%

Increased sensitivity of vegetation to soil moisture and its key mechanisms in the Loess Plateau, China

Wang,

Zhao,

2023

Ecohydrology

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Soil moisture (SM) plays a crucial role in connecting various ecological processes in terrestrial ecosystems, as vegetation growth heavily relies on SM availability. Despite many studies evaluating the impacts of SM on vegetation activity, changes in vegetation sensitivity to SM are still poorly understood. In this study, we evaluated the spatiotemporal changes of vegetation sensitivity to SM across the Loess Plateau (LP) region from 1982 to 2010 using satellite‐based normalised difference vegetation index (NDVI) and reanalysis SM data. Our results showed a significant increase in NDVI (slope = 0.0015/year, p < 0.001) and a slight decrease in SM (slope = −0.0001 m3/m3/year, p = 0.7) over the past 29 years, indicating a greening trend in the LP. By establishing a multiple linear model, we found that the sensitivity of vegetation dynamics to SM has significantly increased during the same period (slope = 0.029, p < 0.05). Spatially, vegetation in over half (51.2%) of the total area showed enhanced sensitivity to SM. Further analysis using the Lindeman–Merenda–Gold method showed that atmospheric CO2 was the major contributor (27.20%) to the sensitivity changes, followed by nitrogen deposition (23.70%) and air temperature (20.11%). Ecosystem structure changes (represented by non‐tree land cover fractions) and precipitation shifts contributed 16.13% and 12.83%, respectively, to sensitivity changes. These findings provide a better understanding of the spatiotemporal pattern and underlying mechanisms of ecosystem sensitivity to SM in the greening and warming LP.

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“…Previous studies have shown that plants can improve their tolerance by increasing the iWUE values to help them grow under drought stress as water stress increases ( Churakova et al., 2020 ; Yang et al., 2021 ). At the same time, high temperature may reduce stomatal conductivity and the transpiration rate of trees in leaves and increase iWUE ( Granda et al., 2014 ; Hararuk et al., 2019 ), but the increase in iWUE did not offset the negative impact of warming on tree growth ( Ren et al., 2022 ), which drove growth declines of about 50% ( Heilman et al., 2021 ). In the course of plant life, water and carbon are so closely connected that it is difficult to separate them.…”

Section: Introductionmentioning

confidence: 99%

Regulating carbon and water balance as a strategy to cope with warming and drought climate in Cunninghamia lanceolata in southern China

Fang

Lin²,

Zhang³

et al. 2022

Front. Plant Sci.

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Human activities have increased the possibility of simultaneous warming and drought, which will lead to different carbon (C) allocation and water use strategies in plants. However, there is no conclusive information from previous studies. To explore C and water balance strategies of plants in response to warming and drought, we designed a 4-year experiment that included control (CT), warming (W, with a 5°C increase in temperature), drought (D, with a 50% decrease in precipitation), and warming and drought conditions (WD) to investigate the non-structural carbohydrate (NSC), C and nitrogen (N) stoichiometry, and intrinsic water use efficiency (iWUE) of leaves, roots, and litter of Cunninghamia lanceolata, a major tree species in southern China. We found that W significantly increased NSC and starch in the leaves, and increased NSC and soluble sugar is one of the components of NSC in the roots. D significantly increased leaves’ NSC and starch, and increased litter soluble sugar. The NSC of the WD did not change significantly, but the soluble sugar was significantly reduced. The iWUE of leaves increased under D, and surprisingly, W and D significantly increased the iWUE of litter. The iWUE was positively correlated with NSC and soluble sugar. In addition, D significantly increased N at the roots and litter, resulting in a significant decrease in the C/N ratio. The principal component analysis showed that NSC, iWUE, N, and C/N ratio can be used as identifying indicators for C. lanceolata in both warming and drought periods. This study stated that under warming or drought, C. lanceolata would decline in growth to maintain high NSC levels and reduce water loss. Leaves would store starch to improve the resiliency of the aboveground parts, and the roots would increase soluble sugar and N accumulation to conserve water and to help C sequestration in the underground part. At the same time, defoliation was potentially beneficial for maintaining C and water balance. However, when combined with warming and drought, C. lanceolata growth will be limited by C, resulting in decreased NSC. This study provides a new insight into the coping strategies of plants in adapting to warming and drought environments.

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Responses of Tree Growth and Intrinsic Water Use Efficiency to Environmental Factors in Central and Northern China in the Context of Global Warming

Cited by 3 publications

References 55 publications

Effects of Geographical and Climatic Factors on the Intrinsic Water Use Efficiency of Tropical Plants: Evidence from Leaf 13C

Effects of Geographical and Climatic Factors on the Intrinsic Water Use Efficiency of Tropical Plants: Evidence from Leaf 13C

Increased sensitivity of vegetation to soil moisture and its key mechanisms in the Loess Plateau, China

Regulating carbon and water balance as a strategy to cope with warming and drought climate in Cunninghamia lanceolata in southern China

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