Dispersion and damping of zone-boundary magnons in the noncentrosymmetric superconductor CePt3Si

TL;DR

This study uses inelastic neutron scattering to analyze spin-wave excitations in CePt3Si, revealing damping effects and deviations from previous models, with no clear signs of superconductivity-related magnetic features.

Contribution

First detailed INS analysis of zone-boundary magnons in CePt3Si showing damping and dispersion deviations in a noncentrosymmetric superconductor.

Findings

Strong spin-wave damping observed

No signatures of superconducting magnetic resonance

Dispersion deviations from prior models

Abstract

Inelastic neutron scattering (INS) is employed to study damped spin-wave excitations in the noncentrosymmetric heavy-fermion superconductor CePt3Si along the antiferromagnetic Brillouin-zone boundary in the low-temperature magnetically ordered state. Measurements along the (1/2 1/2 L) and (H H 1/2-H) reciprocal-space directions reveal deviations in the spin-wave dispersion from the previously reported model. Broad asymmetric shape of the peaks in energy signifies strong spin-wave damping by interactions with the particle-hole continuum. Their energy width exhibits no evident anomalies as a function of momentum along the (1/2 1/2 L) direction, which could be attributed to Fermi-surface nesting effects, implying the absence of pronounced commensurate nesting vectors at the magnetic zone boundary. In agreement with a previous study, we find no signatures of the superconducting transition in the magnetic excitation spectrum, such as a magnetic resonant mode or a superconducting spin gap, either at the magnetic ordering wavevector (0 0 1/2) or at the zone boundary. However, the low superconducting transition temperature in this material still leaves the possibility of such features being weak and therefore hidden below the incoherent background at energies ~0.1 meV, precluding their detection by INS.