Structural and electronic properties of chromium carbides and Fe-substituted chromium carbides

Ganguly, Anindya; Murthy, Vinuthaa; Kannoorpatti, Krishnan

doi:10.1088/2053-1591/ab8cf9

Cited by 16 publications

(6 citation statements)

References 32 publications

(43 reference statements)

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“…Based on the evidence of Cenrichment in the elemental partitioning maps, the dark-contrast precipitates are thought to be a Cr-carbide phase. Three stable Cr-carbide phases have been reported in the literature: Cr23C6 which is fcc, and Cr7C3 and Cr3C2 which both have orthorhombic symmetry [47]. Among them, the Cr23C6 phase is most common and has previously been identified in alloys of this system, due to the intentional [48][49][50][51][52][53][54] and unintentional [11,12,26,27] incorporation of C. Moreover, the composition of the Cr carbide phase closely matched those of the Cr23C6 phase reported in the literature [12,26,27].…”

Section: Crmnfe15conimentioning

confidence: 65%

The influence of Fe variations on the phase stability of CrMnFexCoNi alloys following long-duration exposures at intermediate temperatures

Bloomfield

Christofidou²,

Monni³

et al. 2021

Intermetallics

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Section: Crmnfe15conimentioning

confidence: 65%

The influence of Fe variations on the phase stability of CrMnFexCoNi alloys following long-duration exposures at intermediate temperatures

Bloomfield

Christofidou²,

Monni³

et al. 2021

Intermetallics

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“…APT analysis hence confirms that ≈1.9 wt% of C could be dissolved in the austenite matrix by the solution heat treatment. Cr 7 C 3 is a stable carbide [ 31 ] where W is not expected to be present. We hence detect a higher W content of 0.9 wt% in the austenite matrix from APT analysis compared to the bulk W content obtained from OES which was 0.62 wt%.…”

Section: Resultsmentioning

confidence: 99%

A Carbon‐Stabilized Austenitic Steel with Lower Hydrogen Embrittlement Susceptibility

Khanchandani,

Zeiler,

Strobel

et al. 2023

steel research int.

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High‐strength steels are susceptible to H‐induced failure, which is typically caused by the presence of diffusible H in the microstructure. The diffusivity of H in austenitic steels with face‐centered cubic (fcc) crystal structure is slow. The austenitic steels are hence preferred for applications in the hydrogen‐containing atmospheres. However, the fcc structure of austenitic steels is often stabilized by the addition of Ni, Mn, or N, which are relatively expensive alloying elements to use. Austenite can kinetically also be stabilized using C. Herein, an approach is applied to a commercial cold work tool steel, where C is used to fully stabilize the fcc phase. This results in a microstructure consisting of only austenite and M7C3 carbide. An exposure to H by cathodic hydrogen charging exhibits no significant influence on the strength and ductility of the C‐stabilized austenitic steel. While this material is only a prototype based on an existing alloy of different purposes, it shows the potential for low‐cost H‐resistant steels based on C‐stabilized austenite.

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“…It is known that chromium carbides are widely used in many industries due to their low cost, flexibility, and popularity. The low melting point helps to reduce the heat consumption during the melting process, and the proximity of the temperature coefficient of linear expansion is comparable to that of steels, leads to a decrease in stresses in the transition layer when coating a steel base [15][16]. Therefore, when approaching the creation of a coating of the Fe-Cr-C-Cu-Sn system, the combination of tinbronze and chromium carbide (CrxCy) during plasma heating of their preliminary coating layer can lead to high uniformity due to their high solubility at high temperatures with little attention to substrate dilution.…”

Section: Researchmentioning

confidence: 99%

Microstructure and Wear Resistance of Plasma Surface Layers Based of Alloy Mixture CuSn10/CrxCy

Balanovskiy¹,

Trieu²,

Anatolyevna³

et al. 2022

Tribol. Ind.

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The article relates to the study of the microstructure and wear resistance of the surface layers obtained by plasma heating of the powder-clad layer of the CuSn10 alloy and the coating of the OK 84.78 welding electrode. Microstructure studies, hardness measurements and wear tests have shown that coatings based on a tin-bronze alloy and with the addition of OK 84.78 are successfully obtained. Coating from CuSn10 + 20% alloy mixture OK 84.78 has a hardness of about 500-700 HV, and from CuSn10 alloy it is about 310-564 HV. Meanwhile, the wear resistance also increases in series: Steel St3 < coating (CuSn) < coating (CuSn + 20% OK 84.78).

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Structural and electronic properties of chromium carbides and Fe-substituted chromium carbides

Cited by 16 publications

References 32 publications

The influence of Fe variations on the phase stability of CrMnFexCoNi alloys following long-duration exposures at intermediate temperatures

The influence of Fe variations on the phase stability of CrMnFexCoNi alloys following long-duration exposures at intermediate temperatures

A Carbon‐Stabilized Austenitic Steel with Lower Hydrogen Embrittlement Susceptibility

Microstructure and Wear Resistance of Plasma Surface Layers Based of Alloy Mixture CuSn10/CrxCy

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