Multilayered density profile for noninteracting fermions in a rotating two-dimensional trap

Abstract

We compute exactly the average spatial density for N spinless noninteracting fermions in a 2d harmonic trap rotating with a constant frequency in the presence of an additional repulsive central potential γ/r2. We find that, in the large N limit, the bulk density has a rich and nontrivial profile -- with a hole at the center of the trap and surrounded by a multi-layered "wedding cake" structure. The number of layers depends on N and on the two parameters and γ leading to a rich phase diagram. Zooming in on the edge of the k th layer, we find that the edge density profile exhibits k kinks located at the zeroes of the k th Hermite polynomial. Interestingly, in the large k limit, we show that the edge density profile approaches a limiting form, which resembles the shape of a propagating front, found in the unitary evolution of certain quantum spin chains. We also study how a newly formed droplet grows in size on top of the last layer as one changes the parameters.