Field tuning of spin dynamics in low dimensional Ising-like quantum magnets probed by neutron scattering

Thesis

This thesis presents inelastic neutron scattering (INS) studies of spin dynamics in two different Ising-like quantum magnetic materials as a function of applied magnetic field.

The first material explored is the ferromagnetic Ising chain CoNb₂O₆. The excitations in an Ising chain are independent domain wall quasiparticles, however, additional interactions beyond pure one-dimensional Ising exchange can lead to the formation of a variety of bound states in different regimes of applied magnetic field. The excitations in CoNb₂O₆ are first studied as a function of applied near-longitudinal field. This causes domain walls to become confined into bound states, with the confinement potential tuned by the applied field, from the limit of weak field where there is a Zeeman ladder of bound states to strong field where only two remain. Next, a quantum spin Hamiltonian is refined based on a global fit to the spectrum observed in zero field and in high field applied along two orthogonal directions. A novel method is developed using a combination of linear spinwave theory and exact diagonalization on finite chains to capture the observed bound states as well as the weak interactions between the different chains. Calculations using the refined Hamiltonian quantitatively reproduce not only the spectra to which the data were fit, but also the rich behaviour observed in low transverse field. An intuitive physical picture and fully analytically solved model is proposed for this behaviour based on novel bound states stabilized by the competition between an off-diagonal exchange and transverse field. Finally, the magnetization of CoNb₂O₆ is measured as a function of field up to 16 T, observing evidence for the proximity to the expected transverse-field induced quantum critical point.

The other material studied in this thesis is the frustrated triangular lattice quantum Ising-like antiferromagnet Na₂BaCo(PO₄)₂, whose spectrum is measured using INS as a function of transverse field. In high field, sharp magnons are observed and a spin Hamiltonian is refined based on the observed magnon dispersions. At fields below the transition to the field polarized phase, strong continuum scattering is observed, which dominates at low fields where no magnons are observed. The observed spectrum cannot be explained even qualitatively at low field using a linear spinwave approach including one and two magnon excitations.

Authors: Woodland, L

• DOI: 10.5287/ora-bdnkmvpxd
• Type of award: DPhil
• Level of award: Doctoral
• Awarding institution: University of Oxford
• Language: English
• Keywords: inelastic neutron scattering; quantum magnetism; quantum materials
• Subjects: Physics; Condensed matter