To apply carbon isotope composition (δ13C) analyses of C4 plants to the quantitative reconstruction of paleoclimate, the functional mechanism linking plant δ13C (δ13Cp) to the environment, which is based on the...To apply carbon isotope composition (δ13C) analyses of C4 plants to the quantitative reconstruction of paleoclimate, the functional mechanism linking plant δ13C (δ13Cp) to the environment, which is based on the plants' physiological characteristics and morphological adaptability, must be thoroughly understood. Foxtail millet (Setaria italic) and common millet (Panicum miliaceum), as C4 plants, are representative crops of the rain-fed agriculture present in northern China. Fossil millets are ideal for paleoclimatic studies because of the ease of acquisition and identification to the species level. Modem seeds of foxtail and common millet collected from different habitats of the Chinese Loess Plateau, and their carbon isotope compositions, were an- alyzed and correlated with environmental factors, such as latitude, altitude, temperature, precipitation, water availability, and relative humidity. The results showed that the δ13C of foxtail millet had a significantly negative correlation with latitude (R=-0.46), which may indicate the influence of light. The effect of light on the δ13C of foxtail millet accounted for only 21% of variability, while other climatic factors did not exert significant influences. Thus, the δ13C of foxtail millet was not suitable for extracting climatic information. The δ13C of common millet was significantly and positively correlated with precipitation during the growing period (R=0.75), explaining 56% of variability. The functional mechanisms analyzed, using the plants' physiological characteristics and morphological adaptability, indicated that common millet can adapt to environmental changes because of stomatal sensitivity and some non-stomatal factors. Therefore, the 813C of common millet can record precipitation during growth and is a promising factor for paleoclimatic reconstruction.展开更多
基金supported by the National Natural Science Foundation of China(Grant Nos.41301042&41172161)the National Basic Research Program of China(Grant No.2015CB953803)
文摘To apply carbon isotope composition (δ13C) analyses of C4 plants to the quantitative reconstruction of paleoclimate, the functional mechanism linking plant δ13C (δ13Cp) to the environment, which is based on the plants' physiological characteristics and morphological adaptability, must be thoroughly understood. Foxtail millet (Setaria italic) and common millet (Panicum miliaceum), as C4 plants, are representative crops of the rain-fed agriculture present in northern China. Fossil millets are ideal for paleoclimatic studies because of the ease of acquisition and identification to the species level. Modem seeds of foxtail and common millet collected from different habitats of the Chinese Loess Plateau, and their carbon isotope compositions, were an- alyzed and correlated with environmental factors, such as latitude, altitude, temperature, precipitation, water availability, and relative humidity. The results showed that the δ13C of foxtail millet had a significantly negative correlation with latitude (R=-0.46), which may indicate the influence of light. The effect of light on the δ13C of foxtail millet accounted for only 21% of variability, while other climatic factors did not exert significant influences. Thus, the δ13C of foxtail millet was not suitable for extracting climatic information. The δ13C of common millet was significantly and positively correlated with precipitation during the growing period (R=0.75), explaining 56% of variability. The functional mechanisms analyzed, using the plants' physiological characteristics and morphological adaptability, indicated that common millet can adapt to environmental changes because of stomatal sensitivity and some non-stomatal factors. Therefore, the 813C of common millet can record precipitation during growth and is a promising factor for paleoclimatic reconstruction.
