Recent observations of Europa's surface suggest that chlorides (e.g., NaCl, MgCl₂·nH₂O) exist on Europa's geologically active chaos regions (Fischer et al., 2015; Ligier et al. 2016). Europa's surface is irradiated by high-energy particles, such as electrons, and solar UV light. These irradiations would cause the oxidation of surface materials due to dissociation of H₂O ice and subsequent escape of H₂ into space. Through the irradiation, chlorides on the surface could be oxidized to form oxychlorides, such as chlorates (e.g., Mg(ClO₃)₂·6H₂O) or perchlorates (e.g., NaClO₄, Mg(ClO₄)₂·6H₂O) (e.g., Johnson et al., 2019). However, the oxidation reactions have been poorly investigated based on laboratory experiments.
Here, we perform laboratory experiments to investigate formation of oxychlorides on Europa. We irradiated ~10-keV electron or UV light onto mixtures of H₂O ice and chlorides at temperatures of ~120 K using a newly-developed irradiation experimental system. In addition, we irradiated MeV electron onto mixture of H₂O ice and chlorides using an electron-beam accelerator, ETIGO-III (Tokuchi et al., 1998). Our results show no significant formations of ClO₄ and ClO₃ from chlorides regardless of the experimental conditions. The upper limits of conversion efficiency from NaCl to NaClO₄ are estimated in our experiments. The estimated upper limits of conversion efficiency are 10^-19−10^-20 /electron. Considering the upper limits of conversion efficiency, together with the fluxes of electrons or photons on Europa (Paranicas et al., 2009; Clare et al., 2012), an upper limit abundance of NaClO₄ are estimated as less than ~2 mol% relative to H₂O ice over Europa's surface age (30−100 Myr). Our experimental results and estimations suggest that oxychlorides are minor components as salts and oxidants on Europa's surface.