Abstract
Grassland ecosystems play a critical role in regulating CO2 fluxes into and out of the Earth’s surface. Whereas previous studies have often addressed single fluxes of CO2 separately, few have addressed the relation among and controls of multiple CO2 sub-fluxes simultaneously. In this study, we examined the relation among and controls of individual CO2 fluxes (i.e., GEP, NEP, SR, ER, CR) in three contrasting temperate steppes of north China, as affected by livestock grazing. Our findings show that climatic controls of the seasonal patterns in CO2 fluxes were both individual flux- and steppe type-specific, with significant grazing impacts observed for canopy respiration only. In contrast, climatic controls of the annual patterns were only individual flux-specific, with minor grazing impacts on the individual fluxes. Grazing significantly reduced the mean annual soil respiration rate in the typical and desert steppes, but significantly enhanced both soil and canopy respiration in the meadow steppe. Our study suggests that a reassessment of the role of livestock grazing in regulating GHG exchanges is imperative in future studies.
Highlights
Grassland ecosystems play a critical role in regulating CO2 fluxes into and out of the Earth’s surface
No factors were significantly related to net ecosystem photosynthesis (NEP), a result that agrees with previous studies[13,14]
Klumpp et al indicated that the factors predominantly affecting NEP were plant and soil community structure and/or soil organic matter (SOM) compartments[13]
Summary
Grassland ecosystems play a critical role in regulating CO2 fluxes into and out of the Earth’s surface. Significant positive relations were found between gross ecosystem photosynthesis and air temperature, but only in the grazed meadow steppe and the ungrazed typical steppe (Table 1, both P < 0.05).
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