In this second part of a series of articles dedicated to a detailed analysis of bromine chemistry in the atmosphere we address one (out of two) dominant natural sources of reactive bromine. The two main source categories are the release of bromine from sea salt and the decomposition of bromocarbons by photolysis and reaction with OH. Here, we focus on C₁-bromocarbons. We show that the atmospheric chemistry general circulation model ECHAM5/MESSy realistically simulates their emission, transport and decomposition from the boundary layer up to the mesosphere. We included oceanic emission fluxes of the short-lived bromocarbons CH₂Br₂, CH₂ClBr, CHClBr₂, CHCl₂Br, CHBr₃ and of CH₃Br. The vertical profiles and the surface mixing ratios of the bromocarbons are in general agreement with the (few available) observations, especially in view of the limited information available and the consequent coarseness of the emission fields. For CHBr₃, CHCl₂Br and CHClBr₂ photolysis is the most important degradation process in the troposphere. In contrast to this, tropospheric CH₂Br₂, CH₃Br and CH₂ClBr are more efficiently decomposed by reaction with OH. In the free troposphere approximately one third of the C₁-bromocarbons decomposes by reaction with OH. In the boundary layer the reaction with OH is relatively important, whereas it is negligible in the stratosphere. Our results indicate an approximately 50% longer lifetime of CH₃Br (?1 year) than assumed previously, implying a relatively strong contribution to stratospheric bromine and consequent ozone destruction.