Kai Wang scite author profile

With accumulation of carbon cycle observations and model developments over the past decades, exploring interannual variation (IAV) of terrestrial carbon cycle offers the opportunity to better understand climate–carbon cycle relationships. However, despite growing research interest, uncertainties remain on some fundamental issues, such as the contributions of different regions, constituent fluxes and climatic factors to carbon cycle IAV. Here we overviewed the literature on carbon cycle IAV about current understanding of these issues. Observations and models of the carbon cycle unanimously show the dominance of tropical land ecosystems to the signal of global carbon cycle IAV, where tropical semiarid ecosystems contribute as much as the combination of all other tropical ecosystems. Vegetation photosynthesis contributes more than ecosystem respiration to IAV of the global net land carbon flux, but large uncertainties remain on the contribution of fires and other disturbance fluxes. Climatic variations are the major drivers to the IAV of net land carbon flux. Although debate remains on whether the dominant driver is temperature or moisture variability, their interaction,that is, the dependence of carbon cycle sensitivity to temperature on moisture conditions, is emerging as key regulators of the carbon cycle IAV. On timescales from the interannual to the centennial, global carbon cycle variability will be increasingly contributed by northern land ecosystems and oceans. Therefore, both improving Earth system models (ESMs) with the progressive understanding on the fast processes manifested at interannual timescale and expanding carbon cycle observations at broader spatial and longer temporal scales are critical to better prediction on evolution of the carbon–climate system.

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Spatial network structure of the tourism economy in urban agglomeration: A social network analysis

Gan

Voda

Wang

et al. 2021

Journal of Hospitality and Tourism Management

120

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Physically based simulation of the streamflow decrease caused by sediment‐trapping dams in the middle Yellow River

Shi

Wang

et al. 2015

Hydrol. Process.

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Abstract:As a result of climate change/variation and its aggravation by human activities over the past several decades, the hydrological conditions in the middle Yellow River in China have dramatically changed, which has led to a sharp decrease of streamflow and the drying up of certain tributaries. This paper simulated and analysed the impact of sediment-trapping dams (STDs, a type of large-sized check dam used to prevent sediment from entering the Yellow River main stem) on hydrological processes, and the study area was located in the 3246 km 2 Huangfuchuan River basin. Changes in the hydrological processes were analysed, and periods of natural and disturbed states were defined. Subsequently, the number and distribution of the STDs were determined based on data collected from statistical reports and identified from remote sensing images, and the topological relationships between the STDs and high-resolution river reaches were established. A hydrological model, the digital Yellow River integrated model, was used to simulate the STD impact on the hydrological processes, and the maximum STD impact was evaluated through a comparison between the simulation results with and without the STDs, which revealed that the interception effect of the STDs contributed to the decrease of the streamflow by approximately 39%. This paper also analysed the relationship between the spatial distribution of the STDs and rainfall in the Huangfuchuan River basin and revealed that future soil and water conservation measures should focus on areas with a higher average annual rainfall and higher number of rainstorm hours.

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Harmful algal blooms under changing climate and constantly increasing anthropogenic actions: the review of management implications

Nwankwegu

Huang

et al. 2019

3 Biotech

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Responses of vegetation greenness and carbon cycle to extreme droughts in China

Deng

Wang

et al. 2021

Agricultural and Forest Meteorology

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Kai Wang

Interannual variation of terrestrial carbon cycle: Issues and perspectives

Spatial network structure of the tourism economy in urban agglomeration: A social network analysis

Physically based simulation of the streamflow decrease caused by sediment‐trapping dams in the middle Yellow River

Harmful algal blooms under changing climate and constantly increasing anthropogenic actions: the review of management implications

Responses of vegetation greenness and carbon cycle to extreme droughts in China

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