We present a comprehensive experimental and ab-initio study of the S=1/2 Mo5+ system, KMoOP2O7, and show that it realizes the S=1/2 Heisenberg chain antiferromagnet model. Powder neutron diffraction reveals that KMoOP2O7 forms a magnetic network comprised of pairs of Mo5+ chains within its monoclinic P21/n structure. Antiferromagnetic interactions within the Mo5+ chains are identified through magnetometry measurements and confirmed by analysis of the magnetic specific heat. The latter reveals a broad feature centred on TN=0.54 K, which we ascribe to the onset of long-range antiferromagnetic order. No magnetic Bragg scattering is observed in powder neutron diffraction data collected at 0.05 K, however, which is consistent with a strongly suppressed ordered moment with an upper limit μord<0.15μB. The one-dimensional character of the magnetic correlations in KMoOP2O7 is verified through analysis of inelastic neutron scattering data, resulting in a model with J1≈34 K and J2≈−2 K for the intrachain and interchain exchange interactions, respectively. The origin of these experimental findings are addressed through density-functional theory calculations.
Cite
@article{arxiv.2207.01284,
title = {One-Dimensional Quantum Magnetism in the S = 1/2 Mo(V) system, KMoOP2O7},
author = {Aly H. Abdeldaim and Alexander A. Tsirlin and Jacques Ollivier and Clemens Ritter and Dominic Fortes and Robin S. Perry and Lucy Clark and Gøran J. Nilsen},
journal= {arXiv preprint arXiv:2207.01284},
year = {2023}
}