Experimental and ab initio structural studies of liquid Zr[subscript 2]Ni

Hao, S G; Kramer, M J; Wang, C Z; Ho, K M; Nandi, S; Kreyssig, A; Goldman, A I; Wessels, V; Sahu, K K; Kelton, K F; Hyers, R W; Canepari, S M; Rogers, J R

doi:10.1103/Physrevb.79.104206

Title: Experimental and ab initio structural studies of liquid Zr[subscript 2]Ni

Journal Article · Fri May 01 00:00:00 EDT 2009 · Phys. Rev. B

DOI:https://doi.org/10.1103/Physrevb.79.104206· OSTI ID:1005588

Hao, S G; Kramer, M J; Wang, C Z; Ho, K M; Nandi, S; Kreyssig, A; Goldman, A I; Wessels, V; Sahu, K K; Kelton, K F; Hyers, R W; Canepari, S M; Rogers, J R

High-energy x-ray diffraction and ab initio molecular-dynamics simulations demonstrate that the short-range order in the deeply undercooled Zr{sub 2}Ni liquid is quite nuanced. The second diffuse scattering peak in the total structure factory sharpens with supercooling, revealing a shoulder on the high-Q side that is often taken to be a hallmark of increasing icosahedral order. However, a Voronoi tessellation indicates that only approximately 3.5% of all the atoms are in an icosahedral or icosahedral-like environment. In contrast, a Honeycutt-Andersen analysis indicates that a much higher fraction of the atoms is in icosahedral (15%--18%) or distorted icosahedral (25%--28%) bond-pair environments. These results indicate that the liquid contains a large population of fragmented clusters with pentagonal and distorted pentagonal faces, but the fully developed icosahedral fragments are rare. Interestingly, in both cases, the ordering changes little over the 500 K of cooling. All metrics show that the nearest-neighbor atomic configurations of the most deeply supercooled simulated liquid (1173 K) differ topologically and chemically from those in the stable C16 compound, even though the partial pair distributions are similar. The most significant structural change upon decreasing the temperature from 1673 to 1173 K is an increase in the population of Zr in Ni-centered clusters. The structural differences between the liquid and the C16 increase the nucleation barrier, explaining glass formation in the rapidly quenched alloys.

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Research Organization:: Argonne National Lab. (ANL), Argonne, IL (United States)

Sponsoring Organization:: USDOE

OSTI ID:: 1005588

Journal Information:: Phys. Rev. B, Vol. 79, Issue (10) ; 2009; ISSN 1098-0121

Country of Publication:: United States

Language:: ENGLISH

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36 MATERIALS SCIENCE
ALLOYS
ATOMS
COOLING
DIFFUSE SCATTERING
GLASS
LIQUIDS
METRICS
MOLECULAR DYNAMICS METHOD
NICKEL ALLOYS
NUCLEATION
SIMULATION
TEMPERATURE DEPENDENCE
X-RAY DIFFRACTION
ZIRCONIUM ALLOYS

Title: Experimental and ab initio structural studies of liquid Zr[subscript 2]Ni

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