Gold Polar Intermetallics: Structural Versatility through Exclusive Bonding Motifs

Abstract: The design of new materials with desired chemical and physical characteristics requires thorough understanding of the underlying composition-structure-property relationships and the experimental possibility of their modification through the controlled involvement of new components. From this point of view, intermetallic phases, a class of compounds formed by two or more metals, present an endless field of combinations that produce several chemical compound classes ranging from simple alloys to true ionic compo… Show more

“…The DOS curve for CoSn3Pr exhibits a maximum in the range of −0.5 to −2.5 eV which is significantly closer to the Fermi level than in corresponding palladides, platinides or aurides. 27,29,57 The close vicinity of the Co 3d orbitals to the Fermi level suggests that their role must be more important in valence electron count while the transition metals are usually assumed to not provide valence electrons. Such a narrow distribution of the d orbitals is typical for some ionic platinides where relativistic effects play a crucial role, 58,59 while the p-element containing compounds usually show considerably higher dispersion.…”

An Obscured or Nonexistent Binary Intermetallic, Co₇Pr₁₇, Its Existent Neighbor Co₂Pr₅, and Two New Ternaries in the System Co/Sn/Pr, CoSn₃Pr_1–x, and Co_2–xSn₇Pr₃

“…The DOS curve for CoSn3Pr exhibits a maximum in the range of −0.5 to −2.5 eV which is significantly closer to the Fermi level than in corresponding palladides, platinides or aurides. 27,29,57 The close vicinity of the Co 3d orbitals to the Fermi level suggests that their role must be more important in valence electron count while the transition metals are usually assumed to not provide valence electrons. Such a narrow distribution of the d orbitals is typical for some ionic platinides where relativistic effects play a crucial role, 58,59 while the p-element containing compounds usually show considerably higher dispersion.…”

An Obscured or Nonexistent Binary Intermetallic, Co₇Pr₁₇, Its Existent Neighbor Co₂Pr₅, and Two New Ternaries in the System Co/Sn/Pr, CoSn₃Pr_1–x, and Co_2–xSn₇Pr₃

“…The location of gold in the sixth period of the periodic table lends this element physical and chemical characteristics that are often strikingly different from those of the lighter congeners in group 11. 1 To a large extent, these differences are associated with strong relativistic effects impacting the electronic properties of the gold valence states. 1 , 2 In particular, relativistic stabilization of the 6s 2 electronic configuration results in a high electronegativity of gold, comparable to that of iodine on the Pauling scale, 3 although some recently developed electronegativity scales suggest a somewhat lower value for Au in comparison to I.…”

“… 1 To a large extent, these differences are associated with strong relativistic effects impacting the electronic properties of the gold valence states. 1 , 2 In particular, relativistic stabilization of the 6s 2 electronic configuration results in a high electronegativity of gold, comparable to that of iodine on the Pauling scale, 3 although some recently developed electronegativity scales suggest a somewhat lower value for Au in comparison to I. 4 , 5 For this reason, compounds of Au with other metals frequently reveal a significant transfer of the electron density to the Au atoms, which allows their description as aurides, i.e., phases with anionic Au species.…”

Overlooked Binary Compounds Uncovered in the Reinspection of the La–Au System: Synthesis, Crystal Structures, and Electronic Properties of La₇Au₃, La₃Au₂, and La₃Au₄

“…Polar intermetallic compounds (PICs) form a large class of extended solids, combining electropositive 'active' metals (s-or f-block metals mainly) with electronegative post-transition pblock elements and/or late transition (noble) metals. [1][2] Interest in polar intermetallic compounds were originally driven by their structural diversity and exotic bonding features. [2][3][4][5] In fact, they represent intermediates between semiconductors and typical metallic systems.…”

“…[1][2] Interest in polar intermetallic compounds were originally driven by their structural diversity and exotic bonding features. [2][3][4][5] In fact, they represent intermediates between semiconductors and typical metallic systems. [5][6] Hence, their bonding pictures are often very complex and, it is virtually impossible to apply simple heuristic concepts to reliably deduce their compositions, structural features or the nature of the bonding.…”

Uncovering new transition metal Zintl phases by cation substitution: the crystal chemistry of Ca₃CuGe₃ and Ca_2+nMn_xAg_2−x+zGe_2+n−z (n = 3, 4)