Peak energy clustering and efficiency in compact objects

We study the properties of plasmas containing a low energy thermal photon component at comoving temperature \theta \equiv kT'/m_e c^2 \sim 10^{-5} - 10^{-2} interacting with an energetic electron component, characteristic of, e.g., the dissipation phase of relativistic outflows in gamma-ray bursts (GRB's), X-ray flashes, and blazars. We show that, for scattering optical depths larger than a few, balance between Compton and inverse-Compton scattering leads to the accumulation of electrons at values of $\gamma\beta ~ 0.15 - 0.3$. For optical depths larger than ~ 100, this leads to a peak in the comoving photon spectrum at 1-10 keV, very weakly dependent on the values of the free parameters. In particular, these results are applicable to the internal shock model of GRB, as well as to slow dissipation models, e.g. as might be expected from reconnection, if the dissipation occurs at a sub-photospheric radii. For GRB bulk Lorentz factors ~ 100, this results in observed spectral peaks clustering in the 0.1-1 MeV range, with conversion efficiencies of electron into photon energy in the BATSE range of ~ 30%.