Competition between dimerization and vector chirality in the spin-3/2 J1-J2 Heisenberg chain with uniaxial single-ion anisotropy

Abstract

The spin-3/2 chain is a versatile prototypical platform for the study of competition between different kinds of magnetic orders, with the objective of obtaining a deeper understanding of the corresponding quantum phase transitions. In this work, we investigate the spin-3/2 chain with nearest-neighbor J1, next-nearest-neighbor J2, and uniaxial single-ion anisotropy D terms in the absence of a magnetic field. For positive values of J2/J1 and D/J1, we find seven different phases in a rich phase diagram. Without frustration J2=0, a gapless Luttinger liquid phase remains stable for all D>0. As J2 increases, we observe three phases with distinct dimerized valence bond orders, which show an intricate competition with vector chiral order and incommensurate correlations. For large J2, regions of phase coexistence between the dimerized and vector chiral orders emerge. We present large-scale numerical data for the determination of transition lines, order parameters, and the nature of the phase transitions.