Low-energy structure of the intertwining double-chain ferrimagnets A3Cu3(PO4)4 (A=Ca,Sr,Pb)

Abstract

Motivated by the homometallic intertwining double-chain ferrimagnets A3Cu3(PO4)4 (A=Ca,Sr,Pb), we investigate the low-energy structure of their model Hamiltonian H=Σn[J1(Sn :1+Sn :3) +J2(Sn+1:1+Sn-1:3)]·Sn:2, where Sn:l stands for the Cu2+ ion spin labeled l in the nth trimer unit, with particular emphasis on the range of bond alternation 0<J2/J1<1. Although the spin-wave theory, whether up to O(S1) or up to O(S0), claims that there exists a flat band in the excitation spectrum regardless of bond alternation, a perturbational treatment as well as the exact diagonalization of the Hamiltonian reveals its weak but nonvanishing momentum dispersion unless J2=J1 or J2=0. Quantum Monte Carlo calculations of the static structure factor further convince us of the low-lying excitation mechanism, elucidating similarities and differences between the present system and alternating-spin linear-chain ferrimagnets.