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Eigen microstates and their evolution of global ozone at different geopotential heights.

Xiaojie ChenNa YingDean ChenYongwen ZhangBo LuJingfang FanXiao-Song Chen
Published in: Chaos (Woodbury, N.Y.) (2021)
Studies on stratospheric ozone have attracted much attention due to its serious impacts on climate changes and its important role as a tracer of Earth's global circulation. Tropospheric ozone as a main atmospheric pollutant damages human health as well as the growth of vegetation. Yet, there is still a lack of a theoretical framework to fully describe the variation of ozone. To understand ozone's spatiotemporal variance, we introduce the eigen microstate method to analyze the global ozone mass mixing ratio between January 1, 1979 and June 30, 2020 at 37 pressure layers. We find that eigen microstates at different geopotential heights can capture different climate phenomena and modes. Without deseasonalization, the first eigen microstates capture the seasonal effect and reveal that the phase of the intra-annual cycle moves with the geopotential heights. After deseasonalization, by contrast, the collective patterns from the overall trend, El Niño-Southern Oscillation (ENSO), quasi-biennial oscillation, and tropopause pressure are identified by the first few significant eigen microstates. The theoretical framework proposed here can also be applied to other complex Earth systems.
Keyphrases
  • particulate matter
  • hydrogen peroxide
  • climate change
  • human health
  • risk assessment
  • air pollution
  • high frequency
  • magnetic resonance
  • magnetic resonance imaging
  • working memory
  • genome wide
  • case control