Dark Atoms and their decaying constituents

The nonbaryonic dark matter of the Universe might consist of new stable charged species, bound by ordinary Coulomb interactions in various forms of heavy neutral "dark atoms". The existing models offer natural implementations for the dominant and subdominant forms of dark atom components. In the framework of Walking Technicolor the charge asymmetric excess of both stable negatively doubly charged technilepton $\zeta^{--}$ and metastable but longliving positively doubly charged technibaryon $UU^{++}$ can be generated in the early Universe together with the observed baryon asymmetry. If the excess of $\zeta$ exceeds by several orders of magnitude the excess of $UU$, dark matter might consist dominantly by $He\zeta$ dark atoms of nuclear interacting O-helium ($OHe$) bound state of $\zeta$ with primordial helium. Although sparse, this subdominant component can lead to observable effects, since leptonic decays of technibaryons $UU$ give rise to two positively charged leptons contrary to the pairs of opposite charge leptons created in decays of neutral particles. We show that decays of $UU^{++}\rightarrow e^+ e^+, \mu^+ \mu^+, \tau^+ \tau^+$ of the subdominant $UU\zeta$ component of dark matter, can explain the observed high energy positron excess in the cosmic rays if the fraction of $UU\zeta$ is $\sim 10^{-6}$ of the total dark matter density, the mass of $UU^{++}$ about 1 TeV and the lifetime about $10^{20} $s. Optimizing fit of recent AMS-02 data by model parameters, the predicted mass range of such long-living double charge particle is challenging for its search at the LHC. (abridged)