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<p>The atmospheric carbon dioxide (CO<span class="inline-formula">₂</span>) mixing ratio and its carbon isotope (<span class="inline-formula"><i>δ</i>¹³</span>C-CO<span class="inline-formula">₂</span>) composition contain important CO<span class="inline-formula">₂</span> sink and source information spanning from ecosystem to global scales. The observation and simulation for both CO<span class="inline-formula">₂</span> and <span class="inline-formula"><i>δ</i>¹³</span>C-CO<span class="inline-formula">₂</span> can be used to constrain regional emissions and better understand the anthropogenic and natural mechanisms that control <span class="inline-formula"><i>δ</i>¹³</span>C-CO<span class="inline-formula">₂</span> variations. Such work remains rare for urban environments, especially megacities. Here, we used near-continuous CO<span class="inline-formula">₂</span> and <span class="inline-formula"><i>δ</i>¹³</span>C-CO<span class="inline-formula">₂</span> measurements, from September 2013 to August 2015, and inverse modeling to constrain the CO<span class="inline-formula">₂</span> budget and investigate the main factors that dominated <span class="inline-formula"><i>δ</i>¹³</span>C-CO<span class="inline-formula">₂</span> variations for the Yangtze River delta (YRD) region, one of the largest anthropogenic CO<span class="inline-formula">₂</span> hotspots and densely populated regions in China. We used the WRF-STILT model framework with category-specified EDGAR v4.3.2 CO<span class="inline-formula">₂</span> inventories to simulate hourly CO<span class="inline-formula">₂</span> mixing ratios and <span class="inline-formula"><i>δ</i>¹³</span>C-CO<span class="inline-formula">₂</span>, evaluated these simulations with observations, and constrained the total anthropogenic CO<span class="inline-formula">₂</span> emission. We show that (1) top-down and bottom-up estimates of anthropogenic CO<span class="inline-formula">₂</span> emissions agreed well (bias <span class="inline-formula">&lt;</span> 6 %) on an annual basis, (2) the WRF-STILT model can generally reproduce the observed diel and seasonal atmospheric <span class="inline-formula"><i>δ</i>¹³</span>C-CO<span class="inline-formula">₂</span> variations, and (3) anthropogenic CO<span class="inline-formula">₂</span> emissions played a much larger role than ecosystems in controlling the <span class="inline-formula"><i>δ</i>¹³</span>C-CO<span class="inline-formula">₂</span> seasonality. When excluding ecosystem respiration and photosynthetic discrimination in the YRD area, <span class="inline-formula"><i>δ</i>¹³</span>C-CO<span class="inline-formula">₂</span> seasonality increased from 1.53 ‰ to 1.66 ‰. (4) Atmospheric transport processes in summer amplified the cement CO<span class="inline-formula">₂</span> enhancement proportions in the YRD area, which dominated monthly <span class="inline-formula"><i>δ</i>_s</span> (the mixture of <span class="inline-formula"><i>δ</i>¹³</span>C-CO<span class="inline-formula">₂</span> from all regional end-members) variations. These findings show that the combination of long-term atmospheric carbon isotope observations and inverse modeling can provide a powerful constraint on the carbon cycle of these complex megacities.</p>