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<p>The interannual variability of the greenhouse gases methane (<span class="inline-formula">CH₄</span>) and tropospheric ozone (<span class="inline-formula">O₃</span>) is largely driven by natural variations in global emissions and meteorology. The El Niño–Southern Oscillation (ENSO) is known to influence fire occurrence, wetland emission and atmospheric circulation, affecting sources and sinks of <span class="inline-formula">CH₄</span> and tropospheric <span class="inline-formula">O₃</span>, but there are still important uncertainties associated with the exact mechanism and magnitude of this effect. Here we use a modelling approach to investigate how fires and meteorology control the interannual variability of global carbon monoxide (CO), <span class="inline-formula">CH₄</span> and <span class="inline-formula">O₃</span> concentrations, particularly during large El Niño events. Using a three-dimensional chemical transport model (TOMCAT) coupled to a sophisticated aerosol microphysics scheme (GLOMAP) we simulate changes to CO, hydroxyl radical (OH) and <span class="inline-formula">O₃</span> for the period 1997–2014. We then use an offline radiative transfer model to quantify the climate impact of changes to atmospheric composition as a result of specific drivers.</p> <p>During the El Niño event of 1997–1998, there were increased emissions from biomass burning globally, causing global CO concentrations to increase by more than 40&thinsp;%. This resulted in decreased global mass-weighted tropospheric OH concentrations of up to 9&thinsp;% and a consequent 4&thinsp;% increase in the <span class="inline-formula">CH₄</span> atmospheric lifetime. The change in <span class="inline-formula">CH₄</span> lifetime led to a 7.5&thinsp;ppb&thinsp;yr<span class="inline-formula">⁻¹</span> increase in the global mean <span class="inline-formula">CH₄</span> growth rate in 1998. Therefore, biomass burning emission of CO could account for 72&thinsp;% of the total effect of fire emissions on <span class="inline-formula">CH₄</span> growth rate in 1998.</p> <p>Our simulations indicate that variations in fire emissions and meteorology associated with El Niño have opposing impacts on tropospheric <span class="inline-formula">O₃</span> burden. El Niño-related changes in atmospheric transport and humidity decrease global tropospheric <span class="inline-formula">O₃</span> concentrations leading to a <span class="inline-formula">−0.03</span>&thinsp;W&thinsp;m<span class="inline-formula">⁻²</span> change in the <span class="inline-formula">O₃</span> radiative effect (RE). However, enhanced fire emission of precursors such as nitrogen oxides (<span class="inline-formula">NO_<i>x</i></span>) and CO increase <span class="inline-formula">O₃</span> and lead to an <span class="inline-formula">O₃</span> RE of 0.03&thinsp;W&thinsp;m<span class="inline-formula">⁻²</span>. While globally the two mechanisms nearly cancel out, causing only a small change in global mean <span class="inline-formula">O₃</span> RE, the regional changes are large – up to <span class="inline-formula">−0.33</span>&thinsp;W&thinsp;m<span class="inline-formula">⁻²</span> with potentially important consequences for atmospheric heating and dynamics.</p>