Structure, energetics, and mechanical stability of Fe-Cu bcc alloys from first-principles calculations

Liu, Jefferson Zhe; Walle, Axel van de; Ghosh, Gautam; Asta, Mark

doi:10.1103/physrevb.72.144109

Cited by 130 publications

(75 citation statements)

References 86 publications

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“…Once the cluster expansion is found-the convergence of the expansion is highly system-dependent-the energy of any configuration can be calculated by simply applying Equation (1). Once the ECIs have been determined, the energy of an equivalent random configuration can be obtained from [38]:…”

Section: Alloy Theoretic Approaches To Mixing Energiesmentioning

confidence: 99%

Does aluminum play well with others? Intrinsic Al-A alloying behavior in 211/312 MAX phases

Arróyave

Talapatra

Duong

et al. 2016

Materials Research Letters

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The search for further control over the properties of MAX phases as well as the promise of discovering compounds with new functionalities has resulted in an increased interest in MAX solid solutions resulting from mixing in either the M, A, or X sublattices. The possibility of alloying MAX compounds not only enables finer tuning of their properties but can also be used to stabilize compounds that may otherwise be metastable in their pure state. In this letter, we present an ab initio-based investigation of the intrinsic alloying behavior in the A sublattice of Ti 2 (Al,A)C, Zr 2 (Al,A)C and Ti 3 (Al,A)C 2 MAX compounds. IMPACT STATEMENTIn this work, we present for the first time a comprehensive study of the intrinsic alloying tendencies in MAX solid solutions with (Al,A) mixing in the A sublattice. ARTICLE HISTORY

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Section: Alloy Theoretic Approaches To Mixing Energiesmentioning

confidence: 99%

Does aluminum play well with others? Intrinsic Al-A alloying behavior in 211/312 MAX phases

Arróyave

Talapatra

Duong

et al. 2016

Materials Research Letters

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“…Many factors, such as misfit strengthening, chemical strengthening, modulus difference strengthening, and dislocation coreprecipitate interaction strengthening contribute to the overall Cu precipitate strengthening in steels. [29] The incorrect equation used to describe modulus difference strengthening by Fine and Isheim [29] has been pointed out by Liu et al [30] Since modulus strengthening based upon the model of Russell and Brown [31] plays the most important role among all the factors, the current focus is on evaluating the component of Cu precipitation strengthening provided by modulus strengthening. The Russell-Brown model assumes that the modulus strengthening effect is due to the relative difference in dislocation energy between the matrix and Cu precipitates as a result of the modulus difference, as a dislocation passes from the matrix through the Cu precipitate and back into the matrix.…”

Section: Copper Precipitation Strengtheningmentioning

confidence: 99%

Strength Recovery in a High-Strength Steel During Multiple Weld Thermal Simulations

Caron

Babu

et al. 2011

Metall Mater Trans A

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BlastAlloy 160 (BA160) is a low-carbon martensitic steel strengthened by copper and M 2 C precipitates. Heat-affected zone (HAZ) microstructure evaluation of BA160 exhibited softening in samples subjected to the coarse-grained HAZ thermal simulations of this steel. This softening is partially attributed to dissolution of copper precipitates and metal carbides. After subjecting these coarse-grained HAZs to a second weld thermal cycle below the A c1 temperature (at which austenite begins to form on heating), recovery of strength was observed. Atom-probe tomography and microhardness analyses correlated this strength recovery to re-precipitation of copper precipitates and metal carbides. A continuum model is proposed to rationalize strengthening and softening in the HAZ regions of BlastAlloy 160.

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“…We note that SANS provides precipitate compositions based on questionable assumptions, [61] whereas the APT results are model independent. Additionally, the recent first-principles calculations by Liu et al [55] finds that the shear modulus relevant for dislocation glide varies at absolute 0 K from a negative value of 20 GPa for pure bcc Cu to a positive value of 78 GPa for bcc Fe, with a zero value for compositions near 50 at. pct Fe and 50 at.…”

Section: Atom-probe Tomographymentioning

confidence: 99%

“…[50] The source of this controversy is possibly a result of a combination of a number of precipitation strengthening mechanisms include lattice mismatch, modulus mismatch, and chemical hardening. [51][52][53][54][55][56][57] Also, when the dislocation enters the precipitate two partial dislocations are created that combine when the dislocation leaves the precipitate. Energy must be supplied to move the dislocation out of the precipitate.…”

Section: Atom-probe Tomographymentioning

confidence: 99%

High-Strength Low-Carbon Ferritic Steel Containing Cu-Fe-Ni-Al-Mn Precipitates

Vaynman

Isheim

Kolli³

et al. 2008

Metall Mater Trans A

110

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An investigation of a low-carbon, Fe-Cu-based steel, for Naval ship hull applications, with a yield strength of 965 MPa, Charpy V-notch absorbed impact-energy values as high as 74 J at -40°C, and an elongation-to-failure greater than 15 pct, is presented. The increase in strength is derived from a large number density (approximately 10 23 to 10 24 m -3 ) of copper-iron-nickelaluminum-manganese precipitates. The effect on the mechanical properties of varying the thermal treatment was studied. The nanostructure of the precipitates found within the steel was characterized by atom-probe tomography. Additionally, initial welding studies show that a brittle heat-affected zone is not formed adjacent to the welds.

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Structure, energetics, and mechanical stability of Fe-Cu bcc alloys from first-principles calculations

Cited by 130 publications

References 86 publications

Does aluminum play well with others? Intrinsic Al-A alloying behavior in 211/312 MAX phases

Does aluminum play well with others? Intrinsic Al-A alloying behavior in 211/312 MAX phases

Strength Recovery in a High-Strength Steel During Multiple Weld Thermal Simulations

High-Strength Low-Carbon Ferritic Steel Containing Cu-Fe-Ni-Al-Mn Precipitates

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