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<p>This study estimates the influence of anthropogenic emission reductions on the concentration of particulate matter with a diameter smaller than 2.5 <span class="inline-formula">µ</span>m (PM<span class="inline-formula">_2.5</span>) during the 2020 lockdown period in German metropolitan areas. After accounting for meteorological effects, PM<span class="inline-formula">_2.5</span> concentrations during the spring 2020 lockdown period were 5 % lower compared to the same time period in 2019. However, during the 2020 pre-lockdown period (winter), PM<span class="inline-formula">_2.5</span> concentrations with meteorology accounted for were 19 % lower than in 2019. Meanwhile, NO<span class="inline-formula">₂</span> concentrations with meteorology accounted for dropped by 23 % during the 2020 lockdown period compared to an only 9 % drop for the 2020 pre-lockdown period, both compared to 2019. SO<span class="inline-formula">₂</span> and CO concentrations with meteorology accounted for show no significant changes during the 2020 lockdown period compared to 2019. GEOS-Chem (GC) simulations with a COVID-19 emission reduction scenario based on the observations (23 % reduction in anthropogenic NO<span class="inline-formula">_<i>x</i></span> emission with unchanged anthropogenic volatile organic compounds (VOCs) and SO<span class="inline-formula">₂</span>) are consistent with the small reductions of PM<span class="inline-formula">_2.5</span> during the lockdown and are used to identify the underlying drivers for this. Due to being in a NO<span class="inline-formula">_<i>x</i></span>-saturated ozone production regime, GC OH radical and O<span class="inline-formula">₃</span> concentrations increased (15 % and 9 %, respectively) during the lockdown compared to a business-as-usual (BAU, no lockdown) scenario. O<span class="inline-formula">_<i>x</i></span> (equal to <span class="inline-formula">NO₂+O₃</span>) analysis implies that the increase in ozone at nighttime is solely due to reduced NO titration. The increased O<span class="inline-formula">₃</span> results in increased NO<span class="inline-formula">₃</span> radical concentrations, primarily during the night, despite the large reductions in NO<span class="inline-formula">₂</span>. Thus, the oxidative capacity of the atmosphere is increased in all three important oxidants, OH, O<span class="inline-formula">₃</span>, and NO<span class="inline-formula">₃</span>. PM nitrate formation from gas-phase nitric acid (HNO<span class="inline-formula">₃</span>) is decreased during the lockdown as the increased OH concentration cannot compensate for the strong reductions in NO<span class="inline-formula">₂</span>, resulting in decreased daytime HNO<span class="inline-formula">₃</span> formation from the OH <span class="inline-formula">+</span> NO<span class="inline-formula">₂</span> reaction. However, nighttime formation of PM nitrate from N<span class="inline-formula">₂</span>O<span class="inline-formula">₅</span> hydrolysis is relatively unchanged. This results from the fact that increased nighttime O<span class="inline-formula">₃</span> results in significantly increased NO<span class="inline-formula">₃</span>, which roughly balances the effect of the strong NO<span class="inline-formula">₂</span> reductions on N<span class="inline-formula">₂</span>O<span class="inline-formula">₅</span> formation. Ultimately, the only small observed decrease in lockdown PM<span class="inline-formula">_2.5</span> concentrations can be explained by the large contribution of nighttime PM nitrate formation, generally enhanced sulfate formation, and slightly decreased ammonium. This study also suggests that high PM<span class="inline-formula">_2.5</span> episodes in early spring are linked to high atmospheric ammonia concentrations combined with favorable meteorological conditions of low temperature and low boundary layer height. Northwest Germany is a hot-spot of NH<span class="inline-formula">₃</span> emissions, primarily emitted from livestock farming and intensive agricultural activities (fertilizer application), with high NH<span class="inline-formula">₃</span> concentrations in the early spring and summer months. Based on our findings, we suggest that appropriate NO<span class="inline-formula">_<i>x</i></span> and VOC emission controls are required to limit ozone, and that should also help reduce PM<span class="inline-formula">_2.5</span>. Regulation of NH<span class="inline-formula">₃</span> emissions, primarily from agricultural sectors, could result in significant reductions in PM<span class="inline-formula">_2.5</span> pollution.</p>