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ABSTRACT
The means by which silicon (Si) influences plant growth has important implications for ecology, nature conservation and biogeochemical cycling of Si. To clarify the effect of available soil silicon content on phytolith formation in plants, we studied phytolith in leaves of Phragmites australis (= Phragmites communis), in correlation with available soil silicon, and available silicon in P. australis from 12 sampling sites in Northeast China. The results showed that available soil silicon content and phytolith concentration in P. australis varied across the sampling sites. The differences of available silicon content in P. australis were great among different growing stages. In July and August, silicon absorbed by plant was mainly used for forming phytolith, resulting in a high phytolith concentration, while phytolith concentration was low in September and October. Phytolith concentration was strongly influenced by the ratio of available silicon content in the soil to that in the plant (S/P). The phytolith concentration was high when S/P was less than about 4, and it was low when S/P was more than about 4. The result of redundancy analysis showed that most phytolith morphotypes in P. australis were negatively correlated with S/P. We conclude that silicon uptake of P. australis gradually changes from active uptake to passive uptake when the available soil silicon content is about four times that in P. australis, and in this concentration range the higher available soil silicon content results in phytolith formation. However, if available soil silicon content is too high, it will inhibit phytolith formation.
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Notes on contributors
Jiangyong Wang
Jiangyong Wang is a PhD at Northeast Normal University and has a particular interest in phytoliths. Contribution: He conducted fieldwork and performed the statistical analyses. With the help of all authors he formulated the idea, developed the methodology and wrote the manuscript.
Linjing Liu
Linjing Liu is a engineer at The Institute of Hydrogeology and Environmental Geology, Chinese Academy of Geological Sciences. His field of expertise is quaternary geology. Contribution: He contributed to data collection and discussion of the results, commented on paper drafts and approved the final version.
Zhuo Gao
Zhuo Gao was the postgraduate student involved in the present project. Contribution: She analysed data and collaborated to the manuscript preparation.
Dongmei Jie
Dongmei Jie is full professor at Northeast Normal University. Her field of expertise is quaternary environmental change. Contribution: She collected samples and supervised the experimental design, commented on paper drafts and approved the final version.