Abstract. Deep convection is an efficient mechanism for vertical trace gas transport from Earth's surface to the upper troposphere (UT). The convective redistribution of short-lived trace gases emitted at the surface typically results in a C-shaped profile. This redistribution mechanism can impact photochemical processes, e.g. ozone and radical production in the UT on a large scale due to the generally longer lifetimes of species like formaldehyde (HCHO) and hydrogen peroxide (H₂O₂), which are important HO_x precursors (HO_x =  OH+HO₂ radicals). Due to the solubility of HCHO and H₂O₂ their transport may be suppressed as they are efficiently removed by wet deposition. Here we present a case study of deep convection over Germany in the summer of 2007 within the framework of the HOOVER II project. Airborne in situ measurements within the in- and outflow regions of an isolated thunderstorm provide a unique data set to study the influence of deep convection on the transport efficiency of soluble and insoluble trace gases. Comparing the in- and outflow indicates an almost undiluted transport of insoluble trace gases from the boundary layer to the UT. The ratios of outinflow of CO and CH₄ are 0.94±0.04 and 0.99±0.01, respectively. For the soluble species HCHO and H₂O₂ these ratios are 0.55±0.09 and 0.61±0.08, respectively, indicating partial scavenging and washout. Chemical box model simulations show that post-convection secondary formation of HCHO and H₂O₂ cannot explain their enhancement in the UT. A plausible explanation, in particular for the enhancement of the highly soluble H₂O₂, is degassing from cloud droplets during freezing, which reduces the retention coefficient.