Multiscale approach for studying melting transitions in CuPt nanoparticles

Pavan, Luca; Baletto, Francesca; Novaković, R.

doi:10.1039/c5cp01096a

Cited by 27 publications

(27 citation statements)

References 49 publications

(73 reference statements)

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“…5 right panel, we identify an onion-shell elemental distribution, both according to itMD and NS calculations: the outermost shell contains two thirds of the total copper population; the subsurface is Pt-rich (hitting the ); the third and fourth layers have a 60% of Cu and 40% Pt, respectively. This onion-shell chemical ordering is preserved above the melting point and high temperature NS configurations show that it is the most favourable up to 2500 K, supporting the idea that it should be considered as the equilibrium chemical arrangement, in agreement with previous in-silico 32 , 63 and in-vitro 48 studies. It is interesting to note that in correspondence of the melting transition the radial distribution function identifies an atom at the center of the cluster, while earlier the center of mass of the system felt in between atoms.…”

Section: Resultssupporting

confidence: 87%

“…Metal-metal interactions are modelled following the second moment approximation of the tight binding theory, in the Rosato-Guillope’-Legrande formulation 50 , and their parametrisation is taken from ref. 32 . The choice of a tight binding potential in second-moment approximation (TB-SMA) to describe interatomic interactions is dictated by the long time and length scales involved in our calculations.…”

Section: Methodsmentioning

confidence: 99%

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Thermodynamics of CuPt nanoalloys

Rossi

Partay

Csänyi

et al. 2018

Sci Rep

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The control of structural and chemical transitions in bimetallic nanoalloys at finite temperatures is one of the challenges for their use in advanced applications. Comparing Nested Sampling and Molecular Dynamics simulations, we investigate the phase changes of CuPt nanoalloys with the aim to elucidate the role of kinetic effects during their solidification and melting processes. We find that the quasi-thermodynamic limit for the nucleation of (CuPt)309 is 965 ± 10 K, but its prediction is increasingly underestimated when the system is cooled faster than 109 K/s. The solidified nanoparticles, classified following a novel tool based on Steinhardt parameters and the relative orientation of characteristic atomic environments, are then heated back to their liquid phase. We demonstrate the kinetic origin of the hysteresis in the caloric curve as (i) it closes for rates slower than 108 K/s, with a phase change temperature of 970 K ± 25 K, in very good agreement with its quasi-thermodynamic limit; (ii) the process happens simultaneously in the inner and outer layers; (iii) an onion-shell chemical order - Cu-rich surface, Pt-rich sub-surface, and mixed core - is always preserved.

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Section: Resultssupporting

confidence: 87%

Section: Methodsmentioning

confidence: 99%

Thermodynamics of CuPt nanoalloys

Rossi

Partay

Csänyi

et al. 2018

Sci Rep

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“…To investigate the chemical ordering in the nanoclusters, we have mapped the radial chemical distribution function (RCDF) for the 309 atoms clusters in Figure . Going from the center of mass of nanocluster outwards, the molar ratio of Pt and Co was monitored within the volume delimited by two spherical surfaces, with radii r RCDF and r RCDF + ɛ , respectively ( ɛ is the thickness and was fixed at 0.3 Å) . The white spaces which can be seen in Figure are the regions where no atom exists within a particular radial segment (due to the ordered structure of the solid state).…”

Section: Resultsmentioning

confidence: 99%

“…Therefore, the mixed structure is the most stable structure of the bare and encapsulated Pt/Co nanoclusters. To investigate the chemical ordering in the nanoclusters, we have mapped the radial chemical distribution function (RCDF) [69,70] for the 309 atoms clusters in Figure 6. Going from the center of mass of nanocluster outwards, the molar ratio of Pt and Co was monitored within the volume delimited by two spherical surfaces, with radii r RCDF and r RCDF 1 E, respectively (E is the thickness and was fixed at 0.3 Å ).…”

Section: Structural and Chemical Characterizationmentioning

confidence: 99%

“…Going from the center of mass of nanocluster outwards, the molar ratio of Pt and Co was monitored within the volume delimited by two spherical surfaces, with radii r RCDF and r RCDF 1 E, respectively (E is the thickness and was fixed at 0.3 Å ). [69,70] The white spaces which can be seen in Figure 6 are the regions where no atom exists within a particular radial segment (due to the ordered structure of the solid state). As the cluster is heated, the number of the white spaces decreases which is due to the increasing the structural disorder in the nanocluster.…”

Section: Structural and Chemical Characterizationmentioning

confidence: 99%

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Pt–Co nanocluster in hollow carbon nanospheres

et al. 2018

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Recently, it has been reported that small Pt/Co bimetallic nanoclusters into hollow carbon spheres (HCS) show outstanding catalytic performances in deriving biomass fuels due to the small particle size and the homogeneous alloying. Thus, the knowledge about the thermal evolution and stability of the nanoclusters into the HCS has a great importance. We have simulated the heating process beyond the melting point for the bare and encapsulated Pt/Co clusters into the HCS with the different sizes of 55, 147, and 309. The different thermodynamic and structural properties of the nanoclusters have also been investigated in this work. Our results show that the nanoclusters are more stable into the HCS than the bare clusters. The melting points of the supported clusters are also higher than the unsupported clusters. The confined nanoclusters have also lower excess energy values than the bare clusters which means that the encapsulation of Pt/Co nanoclusters into the HCS is favorable. The structural investigations show that a core-shell structure cannot be observed for the different supported and unsupported clusters and the initial mixed structure of the different nanoclusters remains also at the melting points. To more investigate this claim, the radial chemical distribution function (RCDF) and radial distribution function (RDF) of the bare and encapsulated clusters have also been calculated and discussed. © 2018 Wiley Periodicals, Inc.

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Research into the rationality and the application scopes of different melting models of nanoparticles

Xue

Cui

et al. 2017

J Nanopart Res

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Multiscale approach for studying melting transitions in CuPt nanoparticles

Cited by 27 publications

References 49 publications

Thermodynamics of CuPt nanoalloys

Thermodynamics of CuPt nanoalloys

Pt–Co nanocluster in hollow carbon nanospheres

Research into the rationality and the application scopes of different melting models of nanoparticles

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