Understanding carbon and water dynamics of switchgrass (Panicum virgatum L.) and high biomass sorghum (Sorghum bicolor L. Moench) ecosystems is crucial as the acreage of these feedstocks is expanding for cellulosic biofuels. Net ecosystem exchange (NEE) of CO2 and H2O was measured using eddy covariance system over co-located switchgrass and sorghum fields in south central Oklahoma, USA. The major objectives of this study were to quantify and examine seasonal variations in NEE, evapotranspiration (ET), and ecosystem water use efficiency (EWUE) over switchgrass and sorghum ecosystems in response to controlling factors, and to explore the underlying mechanisms. The results revealed photosynthetic photon flux density (PPFD) as the most significant environmental factor for variation in NEE under optimal weather conditions. However, warm air temperature and high vapor pressure deficit (VPD) obscured the NEE-PPFD relationship. Larger VPD (>3 kPa) limited photosynthesis and asymmetrical diurnal NEE cycles were observed in both ecosystems. Consequently, rectangular hyperbolic light-response curve (NEE partitioning algorithm) consistently failed to provide good fits at high VPD. Modified rectangular hyperbolic light--VPD response model accounted for the limitation of VPD on photosynthesis and improved the model performance significantly. The magnitudes of CO2 and H2O fluxes were similar in both ecosystems during the active growing periods and the differences in carbon sink potential and seasonal water demand were primarily driven by the length of the growing season. Monthly ensemble averaged NEE of switchgrass and sorghum reached seasonal peak values of -33.02 +/- 1.96 and -35.86 +/- 2.32 mumol m-2 s -1, respectively. Similarly, weekly average of daily integrated NEE reached seasonal peaks of -8.5 g C m -2 day -1 in switchgrass and -10.3 g C m -2 day-1 in sorghum. During peak growth, daily ET reached up to 6.2 mm day -1 for switchgrass and 6.7 mm day -1 for sorghum. The EWUE was about 12 g CO2 mm -1 ET in switchgrass and about 10 g CO2 mm -1 ET in sorghum. This research showed strong seasonal carbon sink potential and high water use efficiency of both ecosystems in this region. However, evaluation over a longer term would be more valuable.
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机译:了解柳枝((Panicum virgatum L.)和高生物量高粱(Sorghum bicolor L. Moench)生态系统的碳和水动力学至关重要,因为这些原料的种植面积正在扩大,用于纤维素生物燃料。在美国俄克拉荷马州中南部的同地分布的柳枝and和高粱田上,使用涡度协方差系统测量了CO2和H2O的净生态系统交换(NEE)。这项研究的主要目的是量化和检查柳枝and和高粱生态系统的NEE,蒸散量(ET)和生态系统水分利用效率(EWUE)的季节性变化,以响应控制因素,并探讨其潜在机制。结果表明,在最佳天气条件下,光合光子通量密度(PPFD)是NEE变化的最重要环境因素。然而,温暖的空气温度和高蒸气压亏缺(VPD)掩盖了NEE-PPFD关系。在两个生态系统中均观察到较大的VPD(> 3 kPa)限制的光合作用和不对称的昼夜NEE循环。因此,矩形双曲线光响应曲线(NEE划分算法)始终无法在高VPD时提供良好的拟合。修正的矩形双曲线光-VPD响应模型解决了VPD在光合作用方面的局限性,并显着改善了模型性能。在活跃的生长期中,两个生态系统中的CO2和H2O通量大小相似,碳汇潜力和季节性需水量的差异主要由生长期的长短驱动。柳枝and和高粱的每月合计平均NEE分别达到-33.02 +/- 1.96和-35.86 +/- 2.32 mumol m-2 s -1的季节性峰值。同样,柳枝gra的日均综合NEE的每周平均值达到-8.5 g C m -2 day -1和高粱的-10.3 g C m -2 day-1的季节性高峰。在高峰期生长期间,柳枝daily的每日ET达到6.2 mm -1天,高粱的ET达到6.7 mm -1天。 EWUE在柳枝switch中约为12 g CO2 mm -1 ET,在高粱中约为10 g CO2 mm -1 ET。这项研究表明,该地区的两个生态系统都有强大的季节性碳汇潜力和较高的用水效率。但是,长期评估会更有价值。
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机译:分离的核酸(多核苷酸),反义寡核苷酸,抑制或减少编码CO2SEN蛋白的消息和/或CO2SEN蛋白或植物多聚核苷酸和多肽多糖的植物植株的表达的方法植物保护细胞,植物细胞,植物片,植物组织或植物,植物的一部分的碳吸收量和碳排量的负,正调节及增加,碳保护层和水流以及CO 2 / CO 2交换水交换或损失水开放植物,关闭植物的气孔,部分植物,器官,植物片或植物细胞,以增强或优化植物,植物片,器官,植物,植物的一部分上的生物量积累,植物,种子或植物细胞中的植物细胞或种子,板温度的降低和蒸腾强度的提高,降低了T型保护细胞中的效率降低和碳含量
