Wave functions of the super Tonks-Girardeau gas and the trapped 1D hard sphere Bose gas

Abstract

Recent theoretical and experimental results demonstrate a close connection between the super Tonks-Girardeau (sTG) gas and a 1D hard sphere Bose (HSB) gas with hard sphere diameter nearly equal to the 1D scattering length a1D of the sTG gas, a highly excited gas-like state with nodes only at interparticle separations |xj|=xnode≈ a1D. It is shown herein that when the coupling constant gB in the Lieb-Liniger interaction gBδ(xj) is negative and |x12| xnode, the sTG and HSB wave functions for N=2 particles are not merely similar, but identical; the only difference between the sTG and HSB wave functions is that the sTG wave function allows a small penetration into the region |x12|<xnode, whereas for a HSB gas with hard sphere diameter ah.s.=xnode, the HSB wave function vanishes when all |x12|<ah.s.. Arguments are given suggesting that the same theorem holds also for N>2. The sTG and HSB wave functions for N=2 are given exactly in terms of a parabolic cylinder function, and for N 2, xnode is given accurately by a simple parabola. The metastability of the sTG phase generated by a sudden change of the coupling constant from large positive to large negative values is explained in terms of the very small overlap between the ground state of the Tonks-Girardeau gas and collapsed cluster states.