Comparison of Surface Ozone Variability in Mountainous Forest Areas and Lowland Urban Areas in Southeast China (2024)

Abstract

The ozone (O₃) variations in southeast China are largely different between mountainous forest areas located inland, and lowland urban areas located near the coast. Here, we selected these two kinds of areas to compare their similarities and differences in surface O₃ variability from diurnal to seasonal scales. Our results show that in comparison with the lowland urban areas (coastal areas), the mountainous forest areas (inland areas) are characterized with less human activates, lower precursor emissions, wetter and colder meteorological conditions, and denser vegetation covers. This can lead to lower chemical O₃ production and higher O₃ deposition rates in the inland areas. The annual mean of 8-h O₃ maximum concentrations (MDA8 O₃) in the inland areas are ~15 μg·m⁻³ (i.e. ~15%) lower than that in the coastal areas. The day-to-day variation in surface O₃ in the two types of the areas is rather similar, with a correlation coefficient of 0.75 between them, suggesting similar influences on large scales, such as weather patterns, regional O₃ transport, and background O₃. Over 2016–2020, O₃ concentrations in all the areas shows a trend of “rising and then falling”, with a peak in 2017 and 2018. Daily MDA8 O₃ correlates with solar radiation most in the coastal areas, while in the inland areas, it is correlated with relative humidity most. Diurnally, during the morning, O₃ concentrations in the inland areas increase faster than in the coastal areas in most seasons, mainly due to a faster increase in temperature and decrease in humidity. While in the evening, O₃ concentrations decrease faster in the inland areas than in the coastal areas, mostly attributable to a higher titration effect in the inland areas. Seasonally, both areas share a double-peak variation in O₃ concentrations, with two peaks in spring and autumn and two valleys in summer and winter. We found that the valley in summer is related to the summer Asian monsoon that induces large-scale convections bringing local O₃ upward but blocking inflow of O₃ downward, while the one in winter is due to low O₃ production. The coastal areas experienced more exceedance days (~30 days per year) than inland areas (~5-10 days per year), with O₃ sources largely from the northeast. Overall, the similarities and differences in O₃ concentrations between inland and coastal areas in southeastern China are rather unique, reflecting the collective impact of geographic-related meteorology, O₃ precursor emissions, and vegetation on surface O₃ concentrations.