Tropospheric ozone (O₃) is important as a greenhouse gas, as well as having harmful effects on respiration and photosynthesis. In addition, O₃ is important as an oxidant in the tropospheric photochemical reactions. In recent years, tropospheric ozone have been increasing in Eastern Asia, and thus we must understand the origin and behavior of tropospheric ozone accurately.

In this study, we determined the oxygen isotopic compositions including the triple oxygen isotopic compositions (Δ¹⁷O), by passing air sample through nitrite (NO₂^-)-coated filters, which allows the reaction of O₃ with NO₂^- to produce NO₃^-. The oxygen isotopic composition of NO₃^-was then determined to estimate the oxygen isotopic composition of O₃. To remove atmospheric HNO₃ prior to the reaction between O₃ and NO₂^-, nylon filters were placed before the nitrite-coated filters. In order to obtain a high collection efficiency for the reaction between O₃ and NO₂^-, the O₃ collection was conducted at a flow rate less than 0.5L/min. The NO₂^- on the filter was removed by adding hydrogen azide (N₃H) which selectively converts NO₂^- to N₂O. Then, NO₃^- was converted to N₂O, which is converted to O₂ to be injected into an isotope mass spectrometer (MAT252), allowing quantification on the Δ¹⁷O value of NO₃^-. From the values determined for NO₃^-, the oxygen atoms derived from NO₂^- was subtracted to determine the oxygen isotopic compositions of O₃. Please note that the oxygen isotopic composition determined through this method is not the average isotope composition of oxygen atoms in O₃ (Δ¹⁷O (O₃) _bulk), but is the isotope composition of the oxygen atoms in the terminal positions (Δ¹⁷O (O₃) _terminal) of O₃.
Observation on the atmospheric O₃ was conducted from August to December, 2017, at Nagoya University. The Δ¹⁷O values of ozone were between +32‰~+39‰ which coincided well with those previously determined for tropospheric ozone (35‰±4‰). Besides, the Δ¹⁷O values of ozone were the lowest in August, and were the highest in November. The seasonal variation in the Δ¹⁷O values is most likely due to the stratospheric influence on the tropospheric O₃. We also found about 1‰ differences in the Δ¹⁷O values between day and night. We concluded that the formation of an inversion layer in night time was responsible for the lower Δ¹⁷O values. That is to say, while the ¹⁷O-depleted O₃ produced at ground level heights under the high pressure condition occupied major portion of O₃ in night time due to the inversion layer, the ¹⁷O-enriched O₃ produced at the upper layers contributed to O₃ in day time through the active vertical convection.