Common transport models use the mixing height (MH) to determine turbulent coefficients and to obtain tracer concentrations in the planetary boundary layer (PBL). We conducted a pseudo data experiment to elucidate the impact of assimilating MHs to improve CO₂ transport within the Stochastic Time-Inverted Lagrangian Transport model (STILT). Transport of CO₂ was simulated for August 2006 with a receptor located at Bialystok, Poland. STILT was driven by meteorology obtained from the Weather Research and Forecasting (WRF) model, using the Yonsei University (YSU) and Mellor-Yamada-Janjic (MYJ) PBL parameterizations, which differ substantially in the produced MHs. To quantify model-data mismatch in CO₂ to errors in vertical mixing, we defined the WRF-YSU simulation as known truth. Pseudo MH observations were sampled from WRF-YSU at locations of real radiosonde stations. These point observations were interpolated in space-time to the entire WRF domain using kriging with an external drift, which combines observed and modeled MHs to create a "best guess" MH field. We prescribed MHs in STILT driven by WRF-MYJ winds with the best guess to study the impact on CO ₂ concentrations. Differences in CO₂ between the STILT simulations were on the order of ̃0-1 and ̃1-10 ppm on average (i.e., bias), with standard deviations of ̃1-3 and ̃4-14 ppm (random error) during day (12 UTC) and nighttime (0 UTC), respectively. These were reduced when using STILT with the best guess (̃50%-80% of the bias, ̃10%-20% of the random error). Simulated CO₂ concentrations and MHs were also compared to measurements made at the Bialystok tall tower.