PM_2.5 haze pollution driven by secondary inorganic NO₃^- has been a great concern in East Asia. It is, therefore, imperative to identify its sources and oxidation processes, for which nitrogen and oxygen stable isotopes are powerful tracers. Here, we determined the δ¹⁵N (NO₃^-) and Δ¹⁷O (NO₃^-) of PM_2.5 in Seoul during the summer of 2018 and the winter of 2018-2019 and estimated quantitatively the relative contribution of oxidation pathways for particulate NO₃^- and investigated major NO_x emission sources. In the range of PM_2.5 mass concentration from 7.5 µg m⁻³ (summer) to 139.0 µg m⁻³ (winter), the mean δ¹⁵N was −0.7 ‰ ± 3.3 ‰ and 3.8 ‰ ± 3.7 ‰, and the mean Δ¹⁷O was 23.2 ‰ ± 2.2 ‰ and 27.7 ‰ ± 2.2 ‰ in the summer and winter, respectively. While OH oxidation was the dominant pathway for NO₃^- during the summer (87 %), nighttime formation via N₂O₅ and NO₃ was relatively more important (38 %) during the winter, when aerosol liquid water content (ALWC) and nitrogen oxidation ratio (NOR) were higher. Interestingly, the highest Δ¹⁷O was coupled with the lowest δ¹⁵N and highest NOR during the record-breaking winter PM_2.5 episodes, revealing the critical role of photochemical oxidation process in severe winter haze development. For NO_x sources, atmospheric δ¹⁵N (NO_x) estimated from measured δ¹⁵N (NO₃^-) considering isotope fractionation effects indicates vehicle emissions as the most important emission source of NO_x in Seoul. The contribution from biogenic soil and coal combustion was slightly increased in summer and winter, respectively. Our results built on a multiple-isotope approach provide the first explicit evidence for NO₃^- formation processes and major NO_x emission sources in the Seoul megacity and suggest an effective mitigation measure to improve PM_2.5 pollution.