Momentum-resolved spin-conserving two-triplon bound state and continuum in a cuprate ladder

Studying multi-particle elementary excitations has provided unique access to understand collective many-body phenomena in correlated electronic materials, paving the way towards constructing microscopic models. In this work, we perform O K-edge resonant inelastic X-ray scattering (RIXS) on the quasi-one-dimensional cuprate Sr14Cu24O41 with weakly-doped spin ladders. The RIXS signal is dominated by a dispersing sharp mode -270 meV on top of a damped incoherent component -400-500 meV. Comparing with model calculations using the perturbative continuous unitary transformations method, the two components resemble the spin-conserving ?S = 0 two-triplon bound state and continuum excitations in the spin ladders. Such multi-spin response with long-lived ?S = 0 excitons is central to several exotic magnetic properties featuring Majorana fermions, yet remains unexplored given the generally weak cross-section with other experimental techniques. By investigating a simple spin-ladder model system, our study provides valuable insight into low-dimensional quantum magnetism.

Momentum-resolved spin-conserving two-triplon bound state and continuum in a cuprate ladder

Numerical investigation of bound states in quantum magnets

Magnon-phonon interactions enhance the gap at the Dirac point in the spin-wave spectra of CrI3 two-dimensional magnets

First-principles study of the gap in the spin excitation spectrum of the CrI3 honeycomb ferromagnet

Numerical investigation of bound states in quantum magnets

Magnon-phonon interactions enhance the gap at the Dirac point in the spin-wave spectra of CrI3 two-dimensional magnets

First-principles study of the gap in the spin excitation spectrum of the CrI3 honeycomb ferromagnet