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Computational Materials Science
Elsevier Science Publishers B.V.
Computational Materials Science

Elsevier Science Publishers B.V.

0927-0256

Computational Materials Science/Journal Computational Materials ScienceISTPSCIEI
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    First principles study of the lattice thermal conductivity of alkaline earth oxides

    Ma, YangyangYang, ShuHe, KaihuaLu, Cheng...
    6页
    查看更多>>摘要:Lattice thermal conductivity (k(latt)) is an important physical parameter for understanding the thermal transport and dynamics evolution. Here, we calculate(k(latt)) of alkaline earth metal oxides (MOs, M = Be, Mg, Ca, Sr, Ba) by first principles calculations combined with lattice dynamics theory. Our results indicate that the magnitudes of (k(latt)) of MOs at ambient conditions are closely related to the atomic masses of metal atoms, that is, the lighter atomic masses of metals in MOs possess the larger (k(latt)), which is consistent with the order of alkaline earth metals in Periodic Table. Under high pressure, (k(latt)) of MOs show linearly increase as a function of pressure; meanwhile, the pressure dependence of (k(latt)) is relatively larger for MOs with lighter atomic masses. The calculations show that the structural phase transitions of MOs lead to obvious reductions in (k(latt)) due to the giant variations in scattering rates. By contrast, the effect of phase transition on elastic property and wave velocities are weak, which implies the variation of group velocities are faintly effect on (k(latt)).
      原文链接:
    • NSTL
    • Elsevier

    Twin interaction with E 11 tilt grain boundaries in BCC Fe : Formation of new grain boundaries

    Sainath, G.Nagesha, A.
    7页
    查看更多>>摘要:It is well known that the twinning is an important mode of plastic deformation in nanocrystalline materials. As a result, it is expected that the twin can interact with different grain boundaries (GBs) during the plastic deformation. Understanding these twin-GB interactions is crucial for our understanding of mechanical behavior of materials. In this work, the twin interaction with different E 11 symmetric and asymmetric tilt GBs has been investigated in BCC Fe using molecular dynamics (MD) simulations. The results indicate that twin nucleate from the crack or GB and, its interaction with E 11 asymmetric tilt GBs leads to the formation of a new GB. This new GB consist of (100) Cottrell type immobile dislocations. The detailed atomistic mechanisms responsible for this new GB formation have been revealed using atomistic simulations. Interestingly, the new GB formation has not been observed in the case of twin interaction with E11 symmetric tilt GBs.
      原文链接:
    • NSTL
    • Elsevier

    An atomistic study of self-accommodation martensite morphologies and microstructure evolution during forward and reverse martensitic transformations in single crystal and bicrystal NiTi alloys

    Liu, S.Ke, C. B.Cao, S.Ma, X....
    16页
    查看更多>>摘要:The forward and reverse martensitic transformations in NiTi alloys with different crystallography conditions, in terms of [100]-oriented and [110]-oriented single crystal models as well as a bicrystal model possessing twist grain boundary, are studied deeply using molecular dynamics simulations. An atomic tracing method is proposed to identify the specific numbers of B19 ' martensite variants, hence the self-accommodation martensite morphologies and microstructure evolution during cooling and heating are clearly demonstrated at the atomic scale. The triangular self-accommodation morphology consisted of three correspondence variants (CVs) possessing {111}M type I twin relationships is formed in the NiTi single crystals at the beginning of the martensitic transformation, and stays settled till the end of the transformation. Whereas three types of self-accommodation morphologies including triangular, "herring-bone" and mixed morphologies are formed in the bicrystal, due to the geometrical constraint induced by the grain boundary. The mixed self-accommodation morphology is unstable, which occurs briefly during martensitic transformation and thus evolves into "herring-bone" morphology ultimately. During reverse transformation, B2 austenite phase nucleates preferentially at the triple-junctions of the triangular self-accommodation morphology in NiTi single crystals, and propagates along the junction plane rather than the (001)M compound twin boundaries in the bicrystal alloy.
      原文链接:
    • NSTL
    • Elsevier

    Screening of the mechanical stability of M(2)AX phases for nuclear applications

    Bonny, GiovanniBakaev, AlexanderLambrinou, Konstantina
    5页
    查看更多>>摘要:In the present work, we apply a high-throughput density functional theory (DFT) screening of interesting M(2)AX phase compounds for nuclear applications by assessing their mechanical stability. Evaluation of mechanical stability allows to assess thermodynamically unstable phases and does not require the assessment of competing MX and intermetallic phases. We consider all possible combinations with M = {Ti, Cr, Zr, Nb}, A = {Al, Si, Sn, Pb, Bi} and X = {C}, including "out-of-plane " ordering that is so far unobserved in M(2)AX phases. For all fifty possible combinations, we determine the elastic constants and verify their mechanical stability. In addition, for each combination, the free surface energy is computed and the fracture toughness, K-IC, is determined. The results are discussed in terms of combinations with high mechanical stability and high K-IC. Apart from suggestions of interesting new combinations, the results also form the basis for any plasticity or fracture mechanics model for these MAX phases.
      原文链接:
    • NSTL
    • Elsevier

    Ab-initio investigation of Er3+ defects in tungsten disulfide

    Lopez-Morales, Gabriel, IHampel, AlexanderLopez, Gustavo E.Menon, Vinod M....
    6页
    查看更多>>摘要:We use density functional theory (DFT) to explore the physical properties of an Er-w point defect in monolayer WS2. Our calculations indicate that electrons localize at the dangling bonds associated with a tungsten vacancy (Vw) and at the Er3+ ion site, even in the presence of a net negative charge in the supercell. The system features a set of intra-gap defect states, some of which are reminiscent of those present in isolated Er3+ ions. In both instances, the level of hybridization is low, i.e., orbitals show either strong Er or W character. Through the calculation of the absorption spectrum as a function of wavelength, we identify a broad set of transitions, including one possibly consistent with the Er3+ I-4(15/2) -> I-4(13/2) observed in other hosts. Combined with the low native concentration of spin-active nuclei as well as the two-dimensional nature of the host, these properties reveal Er:WS2 as a potential platform for realizing spin qubits that can be subsequently integrated with other nanoscale optoelectronic devices.
      原文链接:
    • NSTL
    • Elsevier

    Grain boundary kinetics in magnesium alloys from first principles

    Mahjoub, RezaFerry, MichaelStanford, Nikki
    8页
    查看更多>>摘要:Grain boundary migration in magnesium alloys has been studied using quantum mechanical calculations implementing the nudged elastic band method. Four crystallographically different boundaries were examined: two twin boundaries and two general grain boundaries that showed no crystallographic symmetry across the boundary plane. The activation energies for boundary migration were determined from the minimum energy pathways, and these energies were consistent with experimental values. It was found that the activation energy is linearly related to the coordination number of the boundaries. This indicates that boundaries with lower coordination numbers showed smaller activation energies and thus higher mobilities than the more orderly boundaries with larger coordination number and larger activation energies. The effect of solutes at the boundary was also studied, and it was found that most solutes with low co-ordination number decreased the activation energy for boundary migration, but the effect of solutes on boundaries with high coordination number was strongly dependent on the solute chemistry.
      原文链接:
    • NSTL
    • Elsevier

    3D pattern formation from coupled Cahn-Hilliard and Swift-Hohenberg equations: Morphological phases transitions of polymers, bock and diblock copolymers

    Martinez-Agustin, F.Ruiz-Salgado, S.Zenteno-Mateo, B.Rubio, E....
    18页
    查看更多>>摘要:This work proposes a new mathematical model of a ternary mixture composed of coupled Cahn-Hilliard and Swift-Hohenberg equations solved in three dimensions (3D) through a pseudo-spectral implicit method (a numerical method of the fast Fourier transform). The 3D numerical solutions dynamic is analyzed through its structure factor and growth law to study its behavior and some observed phase transitions. These numerical solutions evolve into glassy and crystalline phases in the form of 3D patterns. The new model has a free energy functional that considers small monomers of polymer (or copolymeric) chains taken into the Edwards free energy, as well as solvent-monomers and solvent-stretch free energies whose dynamic is given by the Cahn-Hilliard and Allen-Cahn equations. Isotropic and anisotropic phases from polymers, block, and diblock copolymers blend such that these phases have a morphological diversity of classical and complex structures. As an application of the dynamics of the new ternary model, it has a diversity of morphologies which allows obtaining porous polymeric materials manufactured by a novel 3D printing technique: the mathematical design process and 3D printing assisted manufacturing (MDP-3DPAM). This method allows the proposal of a new technique for the design and creation of polymeric materials with controlled pore size distribution starting with computational modeling.
      原文链接:
    • NSTL
    • Elsevier

    Ensemble-based machine learning models for phase prediction in high entropy alloys

    Mishra, AayeshaKompella, LakshminarayanaSanagavarapu, Lalit MohanVaram, Sreedevi...
    7页
    查看更多>>摘要:High entropy alloys (HEAs), which are multi-component alloys having constituent elements in equi-atomic or near equi-atomic ratios, are receiving immense attention owing to their remarkable mechanical and physical properties. These unusual properties depend on one or more of the phases that these alloy systems constitute, namely solid solution (SS), intermetallic compound (IM), and amorphous (AM) phases. Therefore, phase prediction is crucial in selecting appropriate elements that lead to the formation of a HEA with desirable properties. In this work, machine learning (ML) models are used on a set of design parameters using multi-classification for HEA phase prediction. The ML models comprised ensemble-based (Random Forest and Stacked ensemble) and support vector machine (SVM) methods. To predict solid solution phase formation, researchers used atomic size difference and the parameter Omega = T-m Delta S-mix/vertical bar Delta H-mix vertical bar where T-m is average melting point, Delta S(mix )is entropy of mixing and Delta H-mix is mixing enthalpy. The features used in this study are 51, atomic size difference, average electron concentration, electronegativity difference, average melting point, mean atomic radius, mixing enthalpy, the entropy of mixing, and bulk modulus. The training dataset comprising of 601 as cast alloys is used with cross-validation for test data, and the phases SS, IM, AM, SS + IM, and IM + AM are predicted. The phase prediction accuracies are calculated using one-vs-rest, and precision-recall curves are plotted to determine the model performance. For phases AM, SS, and IM, the stacked ensemble displayed better accuracies when compared to SVM and Random Forest. The findings indicate that the stacked ensemble, which combines weak learners and meta-models, provides accuracy comparable to the neural network model accuracy reported in the literature. These findings provide insights to researchers and practitioners in selecting features and ML models while designing HEAs.
      原文链接:
    • NSTL
    • Elsevier

    Theoretical investigation on the structure of mixed-metal zeolitic imidazolate framework and its interaction with CO2

    Pambudi, Fajar InggitPrasetyo, Niko
    8页
    查看更多>>摘要:Determining the effect of mixed-metal in metal-organic frameworks (MOFs) provides insight into how the distribution of various metal types affects their chemical bonding, electronic properties, particularly net atomic charge distribution and their interaction with guest molecules. In this report, the structural characteristic of the mixed-metal zeolitic imidazolate framework ZIF-8(Cd/Zn) has been thoroughly investigated, employing a periodic density functional theory approach to identify the effect of various locations of different metals. Increasing the fraction of Zn2+ in the mixed-metal ZIFs induces the reduction of lattice parameters and affects the bond distance between metal and linker. Moreover, identification of the chemical bonding present in the mixed-metal ZIFs provides an insight regarding the bond character of the metal to organic linker where Zn-N has a higher bond character than Cd-N, implying a different bond strength. Further confirmation was done by calculating the relative energy of the defective mixed-metal ZIF-8(Cd/Zn) by comparing when either Cd2+ or Zn2+ ions were removed from the structure. Furthermore, the interaction between CO2 and mixed-metal ZIF-8(Cd/Zn) in various positions yielded an overview where different CO2 location affects the binding energy. This study showed how the structure of mixed-metal ZIF-8(Cd/Zn) affects their electronic properties and its consequences on CO2 adsorption.
      原文链接:
    • NSTL
    • Elsevier

    Unraveling the adsorption behaviors of uranium and thorium on the hydroxylated titanium carbide MXene

    Meng, ChengGao, XiyuZou, ShufenNa, Bing...
    8页
    查看更多>>摘要:Hydroxylated titanium carbide Ti3C2(OH)(2), a representative of MXenes, is employed to investigate adsorption behaviors for uranium and thorium using density functional theory based simulation methods. The structural analysis of the complexes compares very well to existing computational and experimental literatures. A closer look at the adsorption configurations and energies indicates that the main adsorption sites are deprotonated O-s atoms of the OH groups terminated on the Ti3C2(OH)(2) MXene surface. The most stable models for U(VI) and Th (IV) adsorbed on the Ti3C2(OH)(2) MXene in the gas phase are bidentate and tridentate configurations, respectively. The adsorption ability of Th(IV) on the Ti3C2(OH)(2 )MXene is stronger than that of U(VI). More importantly, the aqueous solution has a remarkable effect on the coordinated environment of uranyl and Th4+ ions in the binding configurations. Uranyl and Th4+ ions adsorbed on the Ti3C2(OH)(2) MXene in the aqueous environment form pentavalent coordinated structures. Extra OH(- )ligands from water molecules are found to interact with U and Th atoms compared with the adsorption configurations in the gas phase. Moreover, U-O-ax double bonds in the uranyl break to form U-OH bonds in the adsorption model. For all the stable adsorption configurations, the coordinating interaction is the dominant factor, and Th-O-s bonds present more covalent nature than U-O-s bonds due to the larger charge transfers between Th and O-s atoms. This work gives supplement to the experimental observations and will provide deeper insights into the physical chemistry behind the removal of uranium and thorium by using MXenes.
      原文链接:
    • NSTL
    • Elsevier