Microscopic Magnetism of A(TiO)Cu4(PO4)4 (A = Ba, Pb, Sr): 31P and 63,65Cu NMR Study

Abstract

We report a comprehensive NMR study of the chiral square-cupola antiferromagnet Pb(TiO)Cu4(PO4)4 and compare its microscopic hyperfine and local-field parameters with the Ba/Sr analogues in the A(TiO)Cu4(PO4)4 family. Above T N 6.7 K, the 31P Knight shift tracks the bulk susceptibility and yields nearly isotropic transferred hyperfine couplings H hf[010]=6.77(3) and H hf[001]=6.19(3) kOe/μ B. Below T N, the frequency-swept 31P spectrum splits into three lines, in contrast to the four-line pattern reported for BaTCPO. The line separation tracks the onset of the static 31P internal field with a power-law exponent β 0.23, consistent with quasi-two-dimensional criticality. Crystal-rotation 31P NMR in the ordered state resolves all eight symmetry-related P sites and their site-dependent anisotropy. In the ordered state, zero-field 63,65Cu NMR gives a Cu-site internal field B int=14.50(6) T and a quadrupole frequency Q=32.72(5) MHz, while point-charge electric-field-gradient calculations including Sternheimer corrections yield an on-site Cu hole occupancy nd=0.20(4), consistent with a ligand-hole-dominated charge-transfer character. Comparing PbTCPO with BaTCPO and SrTCPO, we find that the transferred hyperfine coupling H hf varies across the series, reflecting changes in local Cu-O-P covalency, whereas the ordered-state 31P internal field in PbTCPO is 69.5 mT, considerably higher than in BaTCPO (35.6 mT) and SrTCPO (34.6 mT). This enhancement is not captured by dipolar terms alone and points to the combined effects of transferred contributions and stacking-dependent cancellation.