Physical and mechanical properties of the B2 compound NiAl

Noebe, Ronald D.; Bowman, Randy R.; Nathal, M. V.

doi:10.1179/095066093790326276

Cited by 225 publications

(240 citation statements)

References 111 publications

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“…This conclusion is in agreement with the experimentally observed strong tendency of constitutional defects in NiAl to avoid the same kind of defect at the first neighbor distance of their sublattice. 2 In order to determine what kind of ordered structure the constitutional defects form in NiAl, additional information regarding the defects interactions at longer distances is necessary. As Table V shows, Ni Al ϪNi Al and V Ni ϪV Ni interactions beyond the second coordination shell are already very weak.…”

Section: Defect Interactionsmentioning

confidence: 99%

“…49 Thermal disorder in the B2-type intermetallics is often of a triple defect type 50 and the triple defect formed by two Ni vacancies and one antisite Ni atom is considered to be the dominant thermal excitation in NiAl. 1,2 The equilibrium concentrations of thermal defects in NiAl have been investigated by means of semiempirical models 51,34,35,52 as well as on the basis of first-principles calculations 18,19,22 and atomic-scale simulations. [53][54][55] The considerations are commonly based on the model of a gas of noninteracting point defects as proposed by Wagner and Schottky.…”

Section: Introductionmentioning

confidence: 99%

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Constitutional and thermal point defects inB2NiAl

et al. 2000

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The formation energies of point defects and the interaction energies of various defect pairs in NiAl are calculated from first principles within an order N, locally self-consistent Green's-function method in conjunction with multipole electrostatic corrections to the atomic sphere approximation. The theory correctly reproduces the ground state for the off-stoichiometric NiAl alloys. The constitutional defects ͑antisite Ni atoms and Ni vacancies in Ni-rich and Al-rich NiAl, respectively͒ are shown to form ordered structures in the ground state, in which they tend to avoid each other at the shortest distance on their sublattice. The dominant thermal defects in Ni-rich and stoichiometric NiAl are calculated to be triple defects. In Al-rich alloys another type of thermal defect dominates, where two Ni vacancies are replaced by one antisite Al atom. As a result, the vacancy concentration decreases with temperature in this region. The effective defect formation enthalpies for different concentration regions of NiAl are also obtained.

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Section: Defect Interactionsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Constitutional and thermal point defects inB2NiAl

et al. 2000

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“…where T is temperature in K and is valid between 300 and 3000 K. The equation was derived by Noebe et al [23] considering a number of published data for polycrystalline materials. It is noted that the CTE of NiAl is a strong function of temperature but not of composition.…”

Section: Cte Of Nialmentioning

confidence: 99%

“…For higher temperatures, isentropic bulk moduli calculated using a first-principles approach by Wang et al [37] Concentration,Temperature were used, after fitting the third-degree polynomial given in Eq. (23). The fitted polynomial coefficients are given in Table 2.…”

Section: Modelling Of the Bulk Modulus Of Phasesmentioning

confidence: 99%

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Modelling the coefficient of thermal expansion in Ni-based superalloys and bond coatings

et al. 2016

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The coefficient of thermal expansion (CTE) of nickel-based superalloys and bond coat layers was modelled by considering contributions from their constituent phases. The equilibrium phase composition of the examined materials was determined using thermodynamic equilibrium software with an appropriate database for Nibased alloys, whereas the CTE and elastic properties of the principal phases were modelled using published data. The CTEs of individual phases were combined using a number of approaches to determine the CTE of the phase aggregate. As part of this work, the expansion coefficients of the superalloy IN-738LC and bond coat Amdry-995 were measured as a function of temperature and compared with the model predictions. The predicted values were also validated with the published data for the single-crystal superalloy CMSX-4 and a number of other Ni-based alloy compositions at 1000 K. A very good agreement between experiment and model output was found, especially up to 800 C. The modelling approaches discussed in this paper have the potential to be an extremely useful tool for the industry and for the designers of new coating systems.

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Strain Hardening

Gray¹,

Pollock²

2002

Intermetallic Compounds ‐ Principles and Practice

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Physical and mechanical properties of the B2 compound NiAl

Cited by 225 publications

References 111 publications

Constitutional and thermal point defects inB2NiAl

Constitutional and thermal point defects inB2NiAl

Modelling the coefficient of thermal expansion in Ni-based superalloys and bond coatings

Strain Hardening

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