大气CO2 浓度升高对绿豆生长及C、N 吸收的影响

Effects of enriched atmospheric CO2 on the growth and uptake of N and C in mung bean

  • 摘要: 研究大气CO2 浓度升高对绿豆生长及C、N 吸收的影响, 有助于了解未来气候变化下绿豆养分平衡的变化。利用FACE (Free Air CO2 Enrichment)系统在大田条件下研究了CO2 浓度升高对绿豆生物量及C、N 吸收的影响。结果表明: 大气CO2 浓度升高使绿豆叶、茎、荚、根、地上部分生物量、总生物量及根冠比增加。各发育期地上部分含N 量下降10.39%~21.06%, 含C 量增加0.41%~1.13%, C/N 增加12.23%~26.68%; 籽粒中N、C 含量及C/N 无显著变化。植株地上部分吸N 量和吸C 量分别增加1.99%~50.87%和14.43%~92.69%。未来大气CO2 浓度升高条件下, 绿豆将通过生物量的增加固定更多的C, 并增加对N 素的吸收, 未来的绿豆生产应考虑增加土壤的施肥水平以保证其养分供应。

     

    Abstract: The inter-governmental panel on climate change projects that atmospheric CO2 will reach 550 μmol·mol-1 by 2050. Elevation of CO2 will invariably influence the growth and yield of mung bean. Research on the growth and uptake of C and N in mung bean in response to elevated CO2 will benefit the study of the balance of nutrients under future climate change. This could provide the scientific basis for high-value mung bean production through the implementation of climate-oriented policies. Contrary to recent studies of crop response to elevated CO2 in chambers and other enclosures, FACE (Free Air CO2 Enrichment) was used in this study. In the study, mung bean was planted under ambient CO2 of 389±40 μmol·mol-1 and FACE regimes of 550±60 μmol·mol-1, respectively. The results showed that leaf, stem, pod, root, above-ground part and total biomass, and root/shoot ratio increased under elevated CO2. Elevated CO2 increased the weight of leaf by 17.15%~80.20% and that of stem by 25.29%~97.38%, compared with ambient CO2. Under FACE, the weight of pod significantly increased by 24.50% at harvest. The weight of root increased by 34.17% and 60.41% at pod-filling and harvest stages, respectively. Elevated CO2 increased above-ground biomass weight by 12.90%~83.09%. Total biomass weight increased by 13.98% and 25.79% at pod-filling and harvest stages, respectively. Root/shoot ratio increased by 18.68% at pod-filling stage. N concentration in above-ground part of mung bean decreased by 10.39%~21.06% under FACE compared with ambient CO2. Elevated CO2 increased C concentration and C/N ratio by 0.41%~1.13% and 12.23%~26.68%, respectively. The change in seed N and C concentration and C/N ratio was insignificant. N and C uptake by above-ground part of mung bean increased by 1.99%~50.87% and 14.43%~92.69%, respectively. Biomass increase suggested higher crop assimilation of C and absorption of soil N under elevated CO2 conditions. This implied that mung bean production could be benefitted from increased levels of soil fertilization which ensures sufficient nutrient supply under elevated CO2 conditions.

     

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