Ecology and Evolution (Sep 2019)

Responses of annual herb plant community characteristics to increased precipitation and reduced wind velocity in semiarid sandy grassland

  • Shan‐Shan Sun,
  • Xin‐Ping Liu,
  • Yu‐Hui He,
  • Shui‐Lian Wei,
  • La‐Mei Zhang,
  • Peng Lv,
  • Chelmeg Bao,
  • Ming‐Ming Wang,
  • Li Cheng

DOI
https://doi.org/10.1002/ece3.5585
Journal volume & issue
Vol. 9, no. 18
pp. 10654 – 10664

Abstract

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Abstract Changes in precipitation regimes and wind velocity tend to alter structure and composition of the annual herb plant community, with consequent effects on ecological functioning and biodiversity maintenance. We examined the effects of increased precipitation and reduced wind velocity on annual herb plant community characteristics via a manipulative experiment from the middle of April to middle of August, 2016. There was significant increment in species richness with increased precipitation from June to August, and there were interactive effects between increased precipitation and reduced wind velocity especially in June and the end of July. From June to August, increased precipitation, reduced wind velocity as well as their interaction stimulated sandy plant community development. There was considerable elevation in plant coverage with increased precipitation, and also there was an interactive effect of increased precipitation with 20% reduced wind velocity. However, reduced wind velocity caused more significant stimulation (p < .01) in plant height. Moreover, dominant plants, Salsola collina, Bassia dasyphylla, and Setaria viridis, contributed equally to the elevated community coverage with increased precipitation, whereas S. collina occupied a much larger proportion on the augment of community height compared with the other two species under the increased precipitation and reduced wind velocity. Elevated Shannon–Wiener index was detected with increased precipitation in June and July. Furthermore, increased precipitation and reduced wind velocity enhanced aboveground and belowground biomass, respectively. These species traits‐in structuring and composing plant community were suggested to be conducive to deep understanding the plant functioning and dynamics under global changing precipitation regimes and atmospheric wind velocity scenarios.

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