Precipitation events reduce soil respiration in a coastal wetland based on four-year continuous field measurements

Han, Guoqi; Sun, Bao-Cun; Chu, Xiaoqing; Xing, Qinghe; Song, Weimin; Xia, Jianyang

doi:10.1016/j.agrformet.2018.03.018

Cited by 93 publications

(69 citation statements)

References 80 publications

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“…Previous study has demonstrated that the average annual precipitation has decreased with a rate of 4.5 mm yr -1 and the annual air temperature has increased by 1.7°C over the past 55 years in the YRD [28]. This shift of precipitation and air temperature might induce drier and hotter seasons in the YRD in the future, which has a great possibility to increase ER, thus greater C loss from this coastal wetland.…”

Section: Discussionmentioning

confidence: 97%

“…Microbiological processes and the roles of microorganisms could be another reason for the variation in ecosystem CO 2 and CH 4 rates. Their activities are controlled by several biological, chemical, and physical factors in soil [19,20,22,28,29,44]. Therefore, soil properties including soil organic carbon (SOC), total nitrogen (TN), inorganic nitrogen, total phosphorus (TP), available phosphorus (AP), salinity, and pH are closely related to CO 2 and CH 4 fluxes [45].…”

Section: Discussionmentioning

confidence: 99%

“…The average annual precipitation is 530–630 mm and the rainfall mostly precipitates from July to September (rainy season). The dry season (April to June) accounts for about 30% of the annual precipitation [28]. The abundant vegetation of this research area includes Phragmites australis , Suaeda heteroptera Kitag , and Tamarix chinensis .…”

Section: Methodsmentioning

confidence: 99%

“…The Yellow River Delta (YRD) wetland, which is the largest wetland ecosystem in the warm temperate zone of China, has an obvious dry season (April to June) and rainy season (July to September) [26–28]. Previous studies have reported seasonal variations in ecosystem C fluxes (CO 2 and CH 4 ) based on continuous flux measurements [28–30] and found that dry-season had the second largest contribution to the CO 2 and CH 4 emissions in the YRD [29]. Therefore, in this study, we emphasized the relationship between dry-season ecosystem C rates (GEP, ER, NEE, and CH 4 ) with vegetation and soil properties and disentangled their contributions to the C rates.…”

Section: Introductionmentioning

confidence: 99%

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Plant biomass and soil organic carbon are main factors influencing dry-season ecosystem carbon rates in the coastal zone of the Yellow River Delta

Wang

et al. 2019

PLoS ONE

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Coastal wetlands are considered as a significant sink of global carbon due to their tremendous organic carbon storage. Coastal CO2 and CH4 flux rates play an important role in regulating atmospheric CO2 and CH4 concentrations. However, the relative contributions of vegetation, soil properties, and spatial structure on dry-season ecosystem carbon (C) rates (net ecosystem CO2 exchange, NEE; ecosystem respiration, ER; gross ecosystem productivity, GEP; and CH4) remain unclear at a regional scale. Here, we compared dry-season ecosystem C rates, plant, and soil properties across three vegetation types from 13 locations at a regional scale in the Yellow River Delta (YRD). The results showed that the Phragmites australis stand had the greatest NEE (-1365.4 μmol m-2 s-1), ER (660.2 μmol m-2 s-1), GEP (-2025.5 μmol m-2 s-1) and acted as a CH4 source (0.27 μmol m-2 s-1), whereas the Suaeda heteroptera and Tamarix chinensis stands uptook CH4 (-0.02 to -0.12 μmol m-2 s-1). Stepwise multiple regression analysis demonstrated that plant biomass was the main factor explaining all of the investigated carbon rates (GEP, ER, NEE, and CH4); while soil organic carbon was shown to be the most important for explaining the variability in the processes of carbon release to the atmosphere, i.e., ER and CH4. Variation partitioning results showed that vegetation and soil properties played equally important roles in shaping the pattern of C rates in the YRD. These results provide a better understanding of the link between ecosystem C rates and environmental drivers, and provide a framework to predict regional-scale ecosystem C fluxes under future climate change.

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Section: Discussionmentioning

confidence: 97%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Plant biomass and soil organic carbon are main factors influencing dry-season ecosystem carbon rates in the coastal zone of the Yellow River Delta

Wang

et al. 2019

PLoS ONE

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“…Coastal wetlands are considered a significant sink for global carbon [30], and Xie et al [31] reported that alkaline/saline soils can absorb CO 2 at a rate of 0.3-3.0 μmol m -2 s -1 with an inorganic, non-biological process. However, unlike these earlier studies, our research has shown that the mean soil respiration of growing seasons in salinized bare land was 0.59 μmol m -2 s -1 , which is similar to the observations of Lai et al [32], who found negative soil respiration only when the temperature was below 5ºC in natural ecosystems of saline/alkaline soils.…”

Section: Discussionmentioning

confidence: 99%

Soil Respiration from Different Halophytic Plants in Coastal Saline-Alkali Soils

Li¹,

Liu²

2020

Pol. J. Environ. Stud.

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Soil salinity is a crucial constraint in the potential utilization of land resources in the coastal regions of northern China [1]. Most of the lands within these areas are covered with salinized soil and are accompanied by shallow underground water [2]. Excess salinity and alkalinity plagued seed germination and plant growth, and led to environmental degradation [3]. In order to improve these conditions, local governments have launched costal ecological restoration projects, including planting halophytes, to recover degraded vegetation and reduce soil salinization. Halophytic plants can grow well and produce high biomass in saline environments

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Reduced magnitude and shifted seasonality of CO₂ sink by experimental warming in a coastal wetland

Sun

Yan

Jiang

et al. 2020

Ecology

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Coastal wetlands have the highest carbon sequestration rate per unit area among all unmanaged natural ecosystems. However, how the magnitude and seasonality of the CO2 sink in coastal wetlands will respond to future climate warming remains unclear. Here, based on measurements of ecosystem CO2 fluxes in a field experiment in the Yellow River Delta, we found that experimental warming (i.e., a 2.4°C increase in soil temperature) reduced net ecosystem productivity (NEP) by 23.7% across two growing seasons of 2017–2018. Such a reduction in NEP resulted from the greater decrease in gross primary productivity (GPP) than ecosystem respiration (ER) under warming. The negative warming effect on NEP mainly occurred in summer (−43.9%) but not in autumn (+61.3%), leading to a shifted NEP seasonality under warming. Further analyses showed that the warming effects on ecosystem CO2 exchange were mainly controlled by soil salinity and its corresponding impacts on species composition. For example, warming increased soil salinity (+35.0%), reduced total aboveground biomass (−9.9%), and benefited the growth of plant species with high salt tolerance and late peak growth. To the best of our knowledge, this study provides the first experimental evidence on the reduced magnitude and shifted seasonality of CO2 exchange under climate warming in coastal wetlands. These findings underscore the high vulnerability of wetland CO2 sink in coastal regions under future climate change.

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Precipitation events reduce soil respiration in a coastal wetland based on four-year continuous field measurements

Cited by 93 publications

References 80 publications

Plant biomass and soil organic carbon are main factors influencing dry-season ecosystem carbon rates in the coastal zone of the Yellow River Delta

Plant biomass and soil organic carbon are main factors influencing dry-season ecosystem carbon rates in the coastal zone of the Yellow River Delta

Soil Respiration from Different Halophytic Plants in Coastal Saline-Alkali Soils

Reduced magnitude and shifted seasonality of CO₂ sink by experimental warming in a coastal wetland

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Precipitation events reduce soil respiration in a coastal wetland based on four-year continuous field measurements

Cited by 93 publications

References 80 publications

Plant biomass and soil organic carbon are main factors influencing dry-season ecosystem carbon rates in the coastal zone of the Yellow River Delta

Plant biomass and soil organic carbon are main factors influencing dry-season ecosystem carbon rates in the coastal zone of the Yellow River Delta

Soil Respiration from Different Halophytic Plants in Coastal Saline-Alkali Soils

Reduced magnitude and shifted seasonality of CO2 sink by experimental warming in a coastal wetland

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Reduced magnitude and shifted seasonality of CO₂ sink by experimental warming in a coastal wetland