Mullin, W. J.Holzmann, M.Laloë, F.2024-04-262024-04-262000-01-01https://hdl.handle.net/20.500.14394/40737This paper was harvested from ArXiv.org and ArXiv identifier is arXiv:0009070v1 The published version is at http://www.springerlink.com/content/l27l778v5359541r/The formalism of Ursell operators provides a self-consistent integral equation for the one-particle reduced operator. In three dimensions this technique yields values of the shift in the Bose-Einstein condensation (BEC) transition temperature, as a function of the scattering length, that are in good agreement with those of Green’s function and quantum Monte Carlo methods. We have applied the same equations to a uniform two-dimensional system and find that, as we alter the chemical potential, an instability develops so that the self-consistent equations no longer have a solution. This instability, which seems to indicate that interactions restore a transition, occurs at a non-zero value of an effective chemical potential. The non-linear equations are limited to temperatures greater than or equal to Tc, so that they do not indicate the nature of the new stable state, but we speculate concerning whether it is a Kosterlitz-Thouless state or a “smeared” BEC, which might avoid any violation of the Hohenberg theorem, as described in an accompanying paper.PhysicsInstability in a Two-Dimensional Dilute Interacting Bose Systemarticle