An increase in mean soil surface temperature has been observed over the last century, and it is predicted to further increase in the future. The effect of increased temperature on ecosystem carbon fluxes in a permanent temperate grassland was studied in a long-term (6 years) field experiment, using multiple temperature increments induced by IR lamps. Ecosystem respiration (R-eco) and net ecosystem exchange (NEE) were measured and modeled by a modified Lloyd and Taylor model including a soil moisture component for R-eco (average R2 of 0.78) and inclusion of a photosynthetic component based on temperature and radiation for NEE (R2 = 0.65). Modeled NEE values ranged between 2.3 and 5.3 kg CO2 m−2 year−1, depending on treatment. An increase of 2 or 3°C led to increased carbon losses, lowering the carbon storage potential by around 4 tonnes of C ha−1 year−1. The majority of significant NEE differences were found during night-time compared to daytime. This suggests that during daytime the increased respiration could be offset by an increase in photosynthetic uptake. This was also supported by differences in δ13C and δ18O, indicating prolonged increased photosynthetic activity associated with the higher temperature treatments. However, this increase in photosynthesis was insufficient to counteract the 24 h increase in respiration, explaining the higher CO2 emissions due to elevated temperature.
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机译:在过去的一个世纪中已经观察到平均土壤表面温度的升高,并且预计将来还会进一步升高。在长期(6年)的野外实验中,研究了温度升高对永久温带草原生态系统碳通量的影响,使用了红外灯引起的多个温度增量。通过改良的劳埃德和泰勒(Lloyd and Taylor)模型对生态系统呼吸(R-eco)和净生态系统交换(NEE)进行了测量和建模,该模型包括R-eco的土壤水分成分(平均R2为0.78)以及基于温度和温度的光合作用成分NEE的辐射(R2 = 0.65)。根据处理方式,模拟的NEE值范围介于2.3和5.3 kg CO2 m-2年-1。升高2或3°C会导致碳损失增加,将碳储存潜力降低约4吨C ha-1 year-1。与白天相比,在夜间发现了大多数明显的NEE差异。这表明白天增加的呼吸可以被光合作用的增加所抵消。 δ13C和δ18O的差异也支持了这一点,表明与高温处理相关的光合作用活性延长。但是,这种光合作用的增加不足以抵消24小时的呼吸增加,这说明温度升高会导致二氧化碳排放量增加。
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