Truncated $\gamma$-exponential models for tidal stellar systems
Abstract
We introduce a parametric family of models to characterize the properties of astrophysical systems in a quasi-stationary evolution under the incidence evaporation. We start from an one-particle distribution that considers an appropriate deformation of Maxwell-Boltzmann form with inverse temperature , in particular, a power-law truncation at the scape energy with exponent . This deformation is implemented using a generalized -exponential function obtained from the \emph{fractional integration} of ordinary exponential. As shown in this work, this proposal generalizes models of tidal stellar systems that predict particles distributions with \emph{isothermal cores and polytropic haloes}, e.g.: Michie-King models. We perform the analysis of thermodynamic features of these models and their associated distribution profiles. A nontrivial consequence of this study is that profiles with isothermal cores and polytropic haloes are only obtained for low energies whenever deformation parameter .
Cite
@article{arxiv.1607.03774,
title = {Truncated $\gamma$-exponential models for tidal stellar systems},
author = {Y. J. Gomez-Leyton and L. Velazquez},
journal= {arXiv preprint arXiv:1607.03774},
year = {2016}
}