Abstract. An ab initio study of gaseous clusters of O₂⁻ and O₃⁻ with water is presented. Based on thorough scans of configurational space, we determine the thermodynamics of cluster growth. The results are in good agreement with benchmark computational methods and existing experimental data. We find that anionic O₂⁻(H₂O)_n and O₃⁻(H₂O)_n clusters are thermally stabilized at typical atmospheric conditions for at least n = 5. The first 4 water molecules are strongly bound to the anion due to delocalization of the excess charge while stabilization of more than 4 H₂O is due to normal hydrogen bonding. Although clustering up to 12 H₂O, we find that the O₂ and O₃ anions retain at least ca. 80 % of the charge and are located at the surface of the cluster. The O₂⁻ and O₃⁻ speicies are thus accessible for further reactions. We consider the distributions of cluster sizes as function of altitude before finally, the thermodynamics of a few relevant cluster reactions are considered.