Dysprosium stannides explained

Under standard conditions, the elements dysprosium and tin combine to form a number of intermetallic compounds, the dysprosium stannides. Dysprosium stannides with simple empirical formulas include Dy₅Sn₃ and DySn₂, but four other intermetallics have intermediate composition. None is believed to survive temperatures higher than 1866C, whereat Dy₅Sn₃ decomposes.^[1] Although dysprosium is a lanthanoid, its f orbitals likely participate in the metallic bonding: mixing dysprosium and tin releases an enthalpy quite different from mixing samarium and tin, with gadolinium and tin intermediate.^[2]

DySn₂ adopts the zirconium disilicide crystal structure, and undergoes a Néel transition around 17K. The magnetic patterning below the Néel point has periods incommensurable with the atomic unit cell, leading to a sinusoidal modulation. Theoretically, DySn₂ should transition at very low temperatures to a different magnetic pattern with commensurable spatial period, but even at 1.5K the incommensurable pattern survives.^[3]

References

1. Okamoto . H. . 2005-04-01 . Dy-Sn (Dysprosium-Tin) . Journal of Phase Equilibria & Diffusion . 26 . 2 . 200–202 . 10.1361/15477030523247.
2. Colinet . C. . Pasturel . A. . Percheron-Guégan . A. . Achard . J.C. . October 1984 . Experimental and calculated enthalpies of formation of rare earth-tin alloys . Journal of the Less Common Metals . 102 . 2 . 173 . 10.1016/0022-5088(84)90313-8.
3. Venturini . G. . Lemoine . P. . Malaman . B. . Ouladdiaf . B. . September 2010 . Magnetic structures of orthorhombic rare earth stannides LSn2 (L=Tb–Tm) . Journal of Alloys and Compounds . 505 . 2 . 404–415 . 10.1016/j.jallcom.2010.06.089.