Interplay between Magnetic and Vestigial Nematic Orders in the Layered J1-J2 Classical Heisenberg Model

Abstract

We study the layered J1-J2 classical Heisenberg model on the square lattice using a self-consistent bond theory. We derive the phase diagram for fixed J1 as a function of temperature T, J2 and interplane coupling Jz. Broad regions of (anti)ferromagnetic and stripe order are found, and are separated by a first-order transition near J2≈ 0.5 (in units of |J1|). Within the stripe phase the magnetic and vestigial nematic transitions occur simultaneously in first-order fashion for strong Jz. For weaker Jz there is in addition, for J2*<J2 < J2**, an intermediate regime of split transitions implying a finite temperature region with nematic order but no long-range stripe magnetic order. In this split regime, the order of the transitions depends sensitively on the deviation from J2* and J2**, with split second-order transitions predominating for J2* J2 J2**. We find that the value of J2* depends weakly on the interplane coupling and is just slightly larger than 0.5 for |Jz| 0.01. In contrast the value of J2** increases quickly from J2* at |Jz| 0.01 as the interplane coupling is further reduced. In addition, the magnetic correlation length is shown to directly depend on the nematic order parameter and thus exhibits a sharp increase (or jump) upon entering the nematic phase. Our results are broadly consistent with predictions based on itinerant electron models of the iron-based superconductors in the normal-state, and thus help substantiate a classical spin framework for providing a phenomenological description of their magnetic properties.