Suppressing atomic diffusion with the Schwarz crystal structure in supersaturated Al–Mg alloys

High atomic diffusivity in metals enables substantial tuneability of their structure and properties by tailoring the diffusional processes, but this causes their customized properties to be unstable at elevated temperatures. Eliminating diffusive interfaces by fabricating single crystals or heavily alloying helps to address this issue but does not inhibit atomic diffusion at high homologous temperatures. We discovered that the Schwarz crystal structure was effective at suppressing atomic diffusion in a supersaturated aluminum–magnesium alloy with extremely fine grains. By forming these stable structures, diffusion-controlled intermetallic precipitation from the nanosized grains and their coarsening were inhibited up to the equilibrium melting temperature, around which the apparent across-boundary diffusivity was reduced by about seven orders of magnitude. Developing advanced engineering alloys using the Schwarz crystal structure may lead to useful properties for high-temperature applications.

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Synthese, Kristallstruktur und Eigenschaften von Triguanidinium-tri--imidocyclotriphosphat-Monohydrat und Tetraguanidinium-tetra-/i-imidocyclotetraphosphat-Tetrahydrat, [C(NH2)3]3(PO2NH)3 · H2O und [C(NH2)3]4(PO2NH)4 · 4 H2O / Synthesis, Crystal Structure, and Properties of Triguanidinium Tri-/i-imidocyclotriphosphate Monohydrate and Tetraguanidinium Tetra-/i-imidocyclotetraphosphate Tetrahydrate, [C(NH2)3]3(PO2NH)3 · H2O and [C(NH2)3]4(PO*NH)4 · 4 H2O

Zeitschrift für Naturforschung B ◽

10.1515/znb-1998-1007 ◽

1998 ◽

Vol 53 (10) ◽

pp. 1115-1126 ◽

Cited By ~ 8

Author(s):

Norbert Stock ◽

Barbara Jürgens ◽

Wolfgang Schnick

Keyword(s):

Crystal Structure ◽

Hydrogen Bonds ◽

Three Dimensional ◽

Chair Conformation ◽

Water Molecules ◽

Structure And Properties ◽

X Ray ◽

Dimensional Network ◽

Diffusion Controlled ◽

Ray Methods

AbstractCoarsely crystalline [C(NH2)3]3(PO2NH)3 · H2O (1) and [C(NH2)3]4(PO2NH)4 · 4 H2O (2) have been obtained by addition of [C(NH2)3]2CO3 to a freshly prepared solution of H3(PO2NH)3 or to a suspension of H4(PO2NH)4 · 2 H2O , respectively, followed by diffusion controlled addition of acetone. The crystal structures of 1 and 2 have been determined by single crystal X-ray methods ([C(NH,)3]3(PO,NH)3 · H2O: Pbca; a = 1565.6(2), b = 1068.31(6), c = 2091.8(2) pm, Z = 8; [C(NH2)3]4(PO2NH)4 · 4 H2O: Pbcn; a = 1739.64(10), b = 1084.19(6), c = 1334.96(11) pm, Z = 4). The P3N3 and P4N4 rings of the anions exhibit the chair conformation. In 1 two cyclic anions are interconnected into pairs via hydrogen bonds. In 2 columns along [001] are formed by hydrogen bonds between the anions. Hydrogen bonding through water molecules and C(NH2)3+ ions results in a three-dimensional network in 2. Complete dehydration is achieved below 160 or 180 °C for 1 or 2, respectively. Heating to 700 °C causes condensation reactions with evolution of NH3 and H2O yielding X-ray amorphous products

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