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<p><span id="page636"/>Quantifying the net carbon flux from land use and land cover changes (<span class="inline-formula"><i>f</i>_LULCC</span>) is critical for understanding the global carbon cycle and, hence, to support climate change mitigation. However, large-scale <span class="inline-formula"><i>f</i>_LULCC</span> is not directly measurable and has to be inferred from models instead, such as semi-empirical bookkeeping models and process-based dynamic global vegetation models (DGVMs). By definition, <span class="inline-formula"><i>f</i>_LULCC</span> estimates are not directly comparable between these two different model types. As an important example, DGVM-based <span class="inline-formula"><i>f</i>_LULCC</span> in the annual global carbon budgets is estimated under transient environmental forcing and includes the so-called loss of additional sink capacity (LASC). The LASC results from the impact of environmental changes on land carbon storage potential of managed land compared to potential vegetation and accumulates over time, which is not captured in bookkeeping models. The <span class="inline-formula"><i>f</i>_LULCC</span> from transient DGVM simulations, thus, strongly depends on the timing of land use and land cover changes mainly because LASC accumulation is cut off at the end of the simulated period. To estimate the LASC, the <span class="inline-formula"><i>f</i>_LULCC</span> from pre-industrial DGVM simulations, which is independent of changing environmental conditions, can be used. Additionally, DGVMs using constant present-day environmental forcing enable an approximation of bookkeeping estimates. Here, we analyse these three DGVM-derived <span class="inline-formula"><i>f</i>_LULCC</span> estimations (under transient, pre-industrial, and present-day forcing) for 12 models within 18 regions and quantify their differences as well as climate- and <span class="inline-formula">CO₂</span>-induced components and compare them to bookkeeping estimates. Averaged across the models, we find a global <span class="inline-formula"><i>f</i>_LULCC</span> (under transient conditions) of <span class="inline-formula">2.0±0.6</span> PgC yr<span class="inline-formula">⁻¹</span> for 2009–2018, of which <span class="inline-formula">∼40</span> % are attributable to the LASC (<span class="inline-formula">0.8±0.3</span> PgC yr<span class="inline-formula">⁻¹</span>). From 1850 onward, the <span class="inline-formula"><i>f</i>_LULCC</span> accumulated to <span class="inline-formula">189±56</span> PgC with <span class="inline-formula">40±15</span> PgC from the LASC. Around 1960, the accumulating nature of the LASC causes global transient <span class="inline-formula"><i>f</i>_LULCC</span> estimates to exceed estimates under present-day conditions, despite generally increased carbon stocks in the latter. Regional hotspots of high cumulative and annual LASC values are found in the USA, China, Brazil, equatorial Africa, and Southeast Asia, mainly due to deforestation for cropland. Distinct negative LASC estimates in Europe (early reforestation) and from 2000 onward in the Ukraine (recultivation of post-Soviet abandoned agricultural land), indicate that <span class="inline-formula"><i>f</i>_LULCC</span> estimates in these regions are lower in transient DGVM compared to bookkeeping approaches. Our study unravels the strong dependence of <span class="inline-formula"><i>f</i>_LULCC</span> estimates on the time a certain land use and land cover change event happened to occur and on the chosen time period for the forcing of environmental conditions in the underlying simulations. We argue for an approach that provides an accounting of the <span class="inline-formula"><i>f</i>_LULCC</span> that is more robust against these choices, for example by estimating a mean DGVM ensemble <span class="inline-formula"><i>f</i>_LULCC</span> and LASC for a defined reference period and homogeneous environmental changes (<span class="inline-formula">CO₂</span> only).</p>