Tuning of<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:mi>L</mml:mi><mml:msub><mml:mn>1</mml:mn><mml:mn>0</mml:mn></mml:msub></mml:mrow></mml:math>atomic order in Co-Pt nanoparticles:<i>Ab initio</i>insights

Chepulskii, Roman V.; Butler, W. H.

doi:10.1103/physrevb.86.155401

Cited by 17 publications

(20 citation statements)

References 107 publications

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“…Temperature mainly affects atomic shells farther than the fourth neighbor distance yielding a 100 K variation of the calculated order-disorder transition temperature. The comparison of EPI with those reported in the literature within the cluster expansion 12 and the tight binding Ising model 22 shows that the TBIM EPI provide a relatively good description of the alloy thermodynamics at temperatures close to ordering temperature (short-range order and temperature of phase transformation), even if they strongly differ from the EPI determined in this study. µ.…”

Section: Discussionsupporting

confidence: 44%

“…The EPI obtained from our measurements are listed in the upper part of Tab. I (ICVM) as well as those reported in the literature 12,22 and based on rigid FCC lattice calculations. The values determined from the neutron diffuse scattering measurements significantly differ from those obtained from the cluster expansion approach (CE) and the tight-binding Ising model (TBIM).…”

Section: B Epi From Inverse Cluster Variation Methodsmentioning

confidence: 58%

“…At the CoPt composition, the derivation of EPI from the formation energy of stable and metastable phases led to a transition temperature which was about half of the measured one 12 . This suggests that some effects not taken into account in the ab initio calculations and in the cluster expansion (CE) formalism 13 prevent the accurate prediction of the transition temperature.…”

Section: Introductionmentioning

confidence: 93%

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Investigations of the Co-Pt alloy phase diagram with neutron diffuse scattering, inverse cluster variation method, and Monte Carlo simulations

et al. 2020

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The short-range order in a CoPt alloy was determined at 1203 K and 1423 K using neutron diffuse scattering measurements. The effective pair interactions provided by data analysis reproduce well the experimental order-disorder transition temperature in Monte Carlo simulations. They complete previous results reported for the Co-Pt system and are compared to those obtained within tightbinding and ab initio formalisms. Our results show that the important dependence of the nearestneighbor pair interactions with composition is not related to the sample magnetic state at the measured temperatures. Interactions measured in the paramagnetic domain for the CoPt alloy behave like those in the ferromagnetic domain for the Co 3 Pt and Co 0.65 Pt 0.35 alloys. The effective pair interactions related to the tight-binding Ising model provide a relatively good description of the CoPt alloy thermodynamics close to the ordering temperature (short-range order and temperature of phase transformation), even if they strongly differ from those measured in this study. The average magnetic moment of Co atoms at high temperatures was determined from the analysis of the intensity contribution that is not dependent on the scattering vector. The obtained value is very close to the moment measured at room temperature or determined from ab initio calculations. This confirms the Curie-Weiss behavior of the CoPt alloy. Finally, transmission electron microscope observations carried out on samples annealed for about 30 days confirmed that the order-disorder transition takes place in the 830 K-843 K temperature interval at the Co 3 Pt composition.

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Section: Discussionsupporting

confidence: 44%

Section: B Epi From Inverse Cluster Variation Methodsmentioning

confidence: 58%

Section: Introductionmentioning

confidence: 93%

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Investigations of the Co-Pt alloy phase diagram with neutron diffuse scattering, inverse cluster variation method, and Monte Carlo simulations

et al. 2020

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“…One crucial question was to characterize the order-disorder transition temperature as a function of the cluster size since theoretical models agree to conclude that it decreases with cluster size [43,44,47,50], which has been experimentally confirmed by high-resolution transmission electron microscopy [33] and by synchrotron X−ray diffraction [28]. Moreover, the nature of the transition displays a first order type as in the bulk as shown by the experimental [28] and theoretical [53] evidences of phase coexistence between the ordered and disordered phases even though there is a smoothing with decreasing cluster size [42,44,47,52].…”

Section: Introductionmentioning

confidence: 57%

“…For example, the effect of the chemical order on the electrocatalytic activity of model PtCo electrodes used in fuel cells has been evident recently [39,40]. Theoretical investigations have been performed on alloy surfaces [7][8][9][10][11], and nanoalloys of Fe-Pt or Co-Pt [41][42][43][44][45][46][47][48][49][50][51][52][53]. The studies on nanoparticles have been mostly concentrated on the equiatomic composition, because of the high magnetic anisotropy of the L1 0 ordered phase in (Fe,Co)-Pt systems, which is expected to compensate the superparamagnetism of nanoparticles used for the nextgeneration recording media for ultrahigh density data storage.…”

Section: Introductionmentioning

confidence: 99%

Ordering and surface segregation inCo1−cPtcnanoparticles: A theoretical study from surface alloys to nanoalloys

et al. 2015

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Monte Carlo simulations within a tight-binding Ising model (TBIM) have been performed on bulk, surfaces, and nanoclusters of Co 1-c -Pt c alloys in order to describe and understand the competition or synergy between surface segregation and chemical ordering phenomena in nanoalloys. Considering effective pair interactions (EPIs) up to the third neighbors, we put in evidence new ordered phases at low temperature in the Co-Pt bulk phase diagram. On the infinite ( 100) and ( 111) surfaces, the Pt surface segregation leads to select the Pt-rich plan at the surface without modification of the bulk ordering in the (100) orientation but with an extension of the ordering on a larger composition range in the (111) orientation as compared to the bulk. The truncated octahedron clusters of 405 and 1289 atoms are studied. Their chemical structure is compared in their core with the bulk phase diagram and in their facets with the ( 111) and ( 100) infinite surfaces segregation isotherms. The cluster core presents an asymmetry as compared to the bulk phase diagram. The (111) facets are similar to the (111) surface, whereas the (100) facets present geometrical frustrations for the segregation versus core ordering.

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Surface composition of magnetron sputtered Pt-Co thin film catalyst for proton exchange membrane fuel cells

Vorokhta

Khalakhan

Václavů

et al. 2016

Applied Surface Science

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Tuning ofL10atomic order in Co-Pt nanoparticles:Ab initioinsights

Cited by 17 publications

References 107 publications

Investigations of the Co-Pt alloy phase diagram with neutron diffuse scattering, inverse cluster variation method, and Monte Carlo simulations

Investigations of the Co-Pt alloy phase diagram with neutron diffuse scattering, inverse cluster variation method, and Monte Carlo simulations

Ordering and surface segregation inCo1−cPtcnanoparticles: A theoretical study from surface alloys to nanoalloys

Surface composition of magnetron sputtered Pt-Co thin film catalyst for proton exchange membrane fuel cells

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