C:N:P stoichiometry in plants and soils of Phragmites australis wetland under different water-salt habitats

doi:10.13287/j.1001-9332.202202.040

Abstract

Abstract: We examined the effects of channel diversion of Yellow River on the content and stoichiometry of carbon (C), nitrogen (N) and phosphorus (P) in the organs of reeds (stem, leaf, rhizome and fibrous root) and soils in three typical Phragmites australis communities in the Yellow River Delta, including P. australis community in the former Yellow River course abandoned in 1996, P. australis community on the new Yellow River course and the P. australis communities on the intertidal area (far from the abandoned and current channel but affected by the tides). The results showed that foliar C, N and P contents of P. australis were highest in the communities of abandoned Yellow River course. Leaf N, stem C and rhizome P contents were highest in the communities of new Yellow River course. Leaf N and stem C and P contents were highest in the communities of intertidal area. The average leaf C (409.48 g·kg^-1) and P (1.09 g·kg^-1) contents in the three habitats were lower than national and global average levels, while leaf N content (21.71 g·kg^-1) was higher than that of national and global average levels. The mean leaf N:P (20.22) was higher than 16 and the mean soil N:P (0.87) was lower than 14, indicating that the P. australis growth in the three habitats was limited by P. Correlation analysis showed that EC was one of the main factors affecting C:N:P stoichiometry in P. australis. In general, the C and P reserves in P. australis in the study area were low, and N reserve was high. The soil organic carbon content was low, the soil C reserves were large, while the N and P were relatively scarce.

Key words: stoichiometry, nutrient content, Phragmites australis, river diversion, the Yellow River Delta

BIAN Fu-hua, WU Qiu-tang, WU Meng-di, GUAN Bo, YU Jun-bao, HAN Guang-xuan. C:N:P stoichiometry in plants and soils of Phragmites australis wetland under different water-salt habitats[J]. Chinese Journal of Applied Ecology, 2022, 33(2): 385-396.

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