Mn(Pt1-xPdx)5P: Isovalent Tuning of Mn Sublattice Magnetic Order
Abstract
We report the growth and characterization of MnPd5P, a ferromagnet with TC ≈ 295 K, and conduct a substitutional study with its antiferromagnetic analogue MnPt5P. We grow single crystals of MnPd5P and Mn(Pt1-xPdx)5P by adding Mn into (Pt1-xPdx)-P based melts. All compounds in the family adopt the layered anti-CeCoIn5 structure with space group P4/mmm, and EDS and XRD results indicate that MnPt5P and MnPd5P form a solid solution. Based on magnetization and resistance data, we construct a T-x phase diagram for Mn(Pt1-xPdx)5P and demonstrate the antiferromagnetic order found in MnPt5P is extraordinarily sensitive to Pd substitution. At low Pd fractions (x < 0.010), the single antiferromagnetic transition in pure MnPt5P splits into a higher temperature ferromagnetic transition followed on cooling by a lower temperature ferromagnetic to antiferromagnetic transition and then by a re-entrant antiferromagnetic to ferromagnetic transition at lower temperatures. The antiferromagnetic region makes up a bubble that persists to x ≈ 0.009 for T ≈ 150 K, with all samples x < 0.009 recovering their initial ferromagnetic state with further cooling to base temperature. Over the same low x range we find a non-monotonic change in the room temperature unit cell volume, further suggesting that pure MnPt5P is close to an instability. Once x > 0.010, Mn(Pt1-xPdx)5P undergoes a single ferromagnetic transition. The Curie temperature increases rapidly with x, rising from TC ≈ 197 K at x = 0.013 to a maximum of TC ≈ 312 K for x ≈ 0.62, and then falls back to TC ≈ 295 K for pure MnPd5P (x = 1). Given that Pt and Pd are isoelectronic, this work raises questions as to the origin of the extreme sensitivity of the magnetic ground state in MnPt5P upon introducing Pd.
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