First-Principles Calculations and CALPHAD Modeling of Thermodynamics

Liu, Zhe

doi:10.1007/s11669-009-9570-6

Cited by 331 publications

(122 citation statements)

References 142 publications

(170 reference statements)

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“…Lukas et al [23], Saunders and Miedownik [24] developed the generalized equilibrium conditions, (software BINGGS for binary systems). Liu used first-principles approach to obtain data necessary for thermodynamic simulations, [25]. Similar work developed, concurrently and independently, in Canada (A.D. Pelton and software FactSage) and in the US (the late Prof. Austin Chen, software PANDAT).…”

Section: Computational Thermodynamics Of Materialsmentioning

confidence: 99%

Modeling of Some Physical Properties of Zirconium Alloys for Nuclear Applications in Support of UFD Campaign

Glazoff¹

2013

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Zirconium-based alloys Zircaloy-2 and Zircaloy-4 are widely used in the nuclear industry as cladding materials for light water reactor (LWR) fuels. These materials display a very good combination of properties such as low neutron absorption, creep behavior, stress-corrosion cracking resistance, reduced hydrogen uptake, corrosion and/or oxidation, especially in the case of Zircaloy-4. However, over the last couple of years, in the post-Fukushima Daiichi world, energetic efforts have been undertaken to improve fuel clad oxidation resistance during off-normal temperature excursions. Efforts have also been made to improve upon the already achieved levels of mechanical behavior and reduce hydrogen uptake. In order to facilitate the development of such novel materials, it is very important to achieve not only engineering control, but also a scientific understanding of the underlying material degradation mechanisms, both in working conditions and in storage of used nuclear fuel.This report strives to contribute to these efforts by constructing the thermodynamic models of both alloys; constructing of the respective phase diagrams, and oxidation mechanisms. A special emphasis was placed upon the role of zirconium suboxides in hydrogen uptake reduction and the atomic mechanisms of oxidation. To that end, computational thermodynamics calculations were conducted concurrently with first-principles atomistic modeling.

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Section: Computational Thermodynamics Of Materialsmentioning

confidence: 99%

Modeling of Some Physical Properties of Zirconium Alloys for Nuclear Applications in Support of UFD Campaign

Glazoff¹

2013

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“…(10)) has been used extensively to model temperature and composition dependent properties for solution phases. [28][29][30] This methodology was chosen due to its ability to provide a consistent means to model all of the properties of interest. Additionally, this approach can be easily expanded and applied to more complex systems (i.e., ternary systems and beyond), which allows for greater utility in the future.…”

Section: B Modeling Physical Properties Of Substratementioning

confidence: 99%

Prediction and characterization of heat-affected zone formation in tin-bismuth alloys due to nickel-aluminum multilayer foil reaction

Hooper

Davis

Johns

et al. 2015

Journal of Applied Physics

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Reactive multilayer foils have the potential to be used as local high intensity heat sources for a variety of applications. Most of the past research effort concerning these materials have focused on understanding the structure-property relationships of the foils that govern the energy released during a reaction. To improve the ability of researchers to more rapidly develop technologies based on reactive multilayer foils, a deeper and more predictive understanding of the relationship between the heat released from the foil and microstructural evolution in the neighboring materials is needed. This work describes the development of a numerical model for the purpose of predicting heat affected zone size in substrate materials. The model is experimentally validated using a commercially available Ni-Al multilayer foils and alloys from the Sn-Bi binary system. To accomplish this, phenomenological models for predicting the variation of physical properties (i.e., thermal conductivity, density, and heat capacity) with temperature and composition in the Sn-Bi system were utilized using literature data.

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“…Since the radiation defects (vacancies and interstitials) occupy the host and interstitial lattices, a general two-sublattice thermodynamic model with multi-components can be used to describe the enthalpy and entropy changes for the alloy system. 51,52 The second term on the right side of Eq. (1) is the gradient energy associated with the interfacial energy of the interstitial loops.…”

Section: Phase-field Model For Interstitial Loop Growth Kinetics and mentioning

confidence: 99%

“…In this case, the sublattice free energy formulism has been extensively used in thermodynamic calculations such as CALPHAD. 52 We suggest using the two-sublattice model shown in Figure 8 to describe the irradiated Fe-Cr alloys. In the ln , (25) where the first summation goes over all sublattices and the second summation goes over all constitutions in the corresponding sublattice.…”

mentioning

confidence: 99%

Phase-field Model for Interstitial Loop Growth Kinetics and Thermodynamic and Kinetic Models of Irradiated Fe-Cr Alloys

Li¹,

Hu²,

Sun³

et al. 2011

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First-Principles Calculations and CALPHAD Modeling of Thermodynamics

Cited by 331 publications

References 142 publications

Modeling of Some Physical Properties of Zirconium Alloys for Nuclear Applications in Support of UFD Campaign

Modeling of Some Physical Properties of Zirconium Alloys for Nuclear Applications in Support of UFD Campaign

Prediction and characterization of heat-affected zone formation in tin-bismuth alloys due to nickel-aluminum multilayer foil reaction

Phase-field Model for Interstitial Loop Growth Kinetics and Thermodynamic and Kinetic Models of Irradiated Fe-Cr Alloys

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