Authors: A. Chen¹, M. Kapoor², L. Rodriguez¹ Affiliations: ¹Laboratory for Atmospheric Physics, ETH Zürich; ²Remote Sensing Division, NOAA
[ R(\lambda) = \fracI(\lambda)I_0(\lambda) \cdot \exp\left(-\mu \cdot \Omega \cdot \sigma(\lambda, T, P)\right) ] ozone imager v2
| Metric | OIv2 | OMI (Aura) | |--------|------|-------------| | Nadir resolution | 1.5 km | 13×24 km | | Swath width | 1200 km | 2600 km | | TCO RMSE vs. Dobson | 2.8% | 3.5% | | Signal-to-noise ratio (312 nm) | 450 | 180 | OIv2 resolved a 120 DU depletion zone within a pyrocumulonimbus plume over Tasmania – a feature smoothed out in OMI data. The 1.5 km imagery revealed filamentary ozone transport structures consistent with WRF-Chem simulations. 5. Discussion OIv2 demonstrates that fine-scale ozone variability is ubiquitous, particularly near urban centers, biomass burning, and mountain waves. The ability to resolve <5 km features challenges the assumption of spatial homogeneity in satellite ozone validation. Future work includes assimilation into GEOS-Chem and operational UV index forecasting. Authors: A