The Magnetocaloric Effect in Exotic Spin Chain Compounds

The seminal S=1/2 chain model is highly sensitive to deviations from the ideal Hamiltonian which, together with the intrinsic quantum fluctuations due to low-dimensionality, can induce a range of exotic behaviours. One such perturbation is an alternating local crystal structure, which produces a field-induced gap to solitonic excitations and promotes non-collinear spin structures. The sine-Gordon (SG) model captures this behaviour at low fields, but breaks down as systems approach saturation. We report the results of pulsed-field adiabatic measurements of the magnetocaloric effect in the archetypal SG chain material [(pym)-Cu(NO₃)₂(H₂O)₂], plus the novel chiral spin-chain compound with four-fold periodicity along the chain axis: [Cu(pym)(H₂O)₄]SiF₆.H₂O, (pym=N₂C₄H₄). The chiral system displays a rich variety of excitations above a gap which, in contrast to the SG model, has a linear field-dependence and suppressed magnitude. These measurements provide a powerful means of probing both the magnetic entropy across phase diagrams, and the quantum critical behaviour near saturation. Our results highlight similar underlying physics in the compounds, but also indicate intriguing qualitative differences in the quantum phase transitions at high field.