The Prolific Ternary System Pt/Sn/Nd: Insertion of Pt into the Structures of Sn/Nd Intermetallics Yields Structural Complexity and Wealth.

The understanding of structure and bonding in intermetallic phases still lags behind that of molecular compounds. For that reason, exploring intermetallic phases and identifying structural patterns and relationships are particularly important for closing this knowledge gap. In particular, here we report on the addition of increasing amounts of platinum to ∼2:1 mixtures of tin and neodymium, which yields eight ternary Pt/Sn/Nd compounds, four of which have not been reported before.

Binary Intermetallics in the 70 atom % R Region of Two R-Pd Systems (R = Tb and Er): Hidden, Obscured, or Nonexistent?

Although rare-earth-metal-transition-metal (R/T) phase diagrams have been explored extensively, our recent studies have uncovered new previously nonexistent binary intermetallics. These compounds belong to a narrow region between 70 and 71.4 atom % of the rare-earth metal but represent four different structure types.

Ternary Polar Intermetallics within the Pt/Sn/R Systems (R = La-Sm): Stannides or Platinides?

Starting generally with a 4:6:3 molar ratio of Pt, Sn, and (where = La-Sm), with or without the application of a NaCl flux, seven ternary compounds were obtained as single crystals. The platinides PtSnR ( = La-Nd) crystallize with the PtGePr type of structure (52, , = 27.6-27.

From the Nonexistent Polar Intermetallic PtPr via PtPr to Pt/Sn/Pr Ternaries.

Although the Pt-Pr phase diagram has been explored well, recent work on rare-earth metal cluster halides with endohedral transition metal atoms has provided a new binary intermetallic that is nonexistent in the known phase diagram: The binary PtPr (1) crystallizes in a new structure type ( mP56, P2/ c, a = 12.353(2) Å, b = 7.4837(9) Å, c = 17.