On the prediction and the formation of the sigma phase in CrMnCoFeNix high entropy alloys

Christofidou, Katerina A.; McAuliffe, Thomas; Mignanelli, P. M.; Stone, H.J.; Jones, N.G.

doi:10.1016/j.jallcom.2018.08.032

Cited by 70 publications

(28 citation statements)

References 35 publications

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“…THERMOCALC software version 2018 (Thermo-Calc Software AB, Solna, Sweden) was used to calculate the phase composition prediction. Unfortunately, the currently developed HEA database (TCHEA1) could not be used as it does not involve interstitial elements, and its accuracy was questioned [ 16 ]. As such, THERMOCALC calculations were realized using an Ni-based alloy database (TCNI9) instead.…”

Section: Methodsmentioning

confidence: 99%

Nitrogen Interstitial Alloying of CoCrFeMnNi High Entropy Alloy through Reactive Powder Milling

Moravčík

Gouvea

Čupera

et al. 2019

Entropy

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The present work is focused on the synthesis of CoCrFeMnNi high entropy alloy (HEA) interstitially alloyed with nitrogen via powder metallurgy routes. Using a simple method, nitrogen was introduced to the HEA from the protective N2 gas atmosphere during mechanical alloying (MA) processing. The lattice parameter and amount of nitrogen in HEA were observed to be linearly proportional to the milling duration. The limited solubility of nitrogen in the main face centered cubic (FCC) phase resulted in the in-situ formation of nitrides and, accordingly, significant increase in the hardness values. It has been shown that fabrication of such nitrogen-doped HEA bulk materials can be conveniently achieved by a simple combination of MA + spark plasma sintering processes, without the need for adding nitrogen from other sources.

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Section: Methodsmentioning

confidence: 99%

Nitrogen Interstitial Alloying of CoCrFeMnNi High Entropy Alloy through Reactive Powder Milling

Moravčík

Gouvea

Čupera

et al. 2019

Entropy

View full text Add to dashboard Cite

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“…One such approach is the CALPHAD method [25], which has proven highly effective in more conventional alloy systems. However, the underpinning thermodynamic databases are predominantly based on the phase equilibria of binary and, to a lesser extent, ternary systems and an increasing body of evidence shows that the fidelity of their predictions in higher order systems, particularly at near-equiatomic compositions, is unreliable [18,[26][27][28][29][30][31]. Furthermore, many studies of phase stability in HEAs have focused on temperatures in excess of 1000˚C [18,28,30], where single-phase solid solutions are more likely to form due to the enhanced entropic contribution to Gibbs energy.…”

Section: Introductionmentioning

confidence: 99%

“…This is particularly true when investigating phase stability at low homologous temperatures, where there may be severe kinetic limitations to phase formation, as evidenced in recent radiotracer studies [33][34][35]. So far, comparisons of CALPHAD predictions, using the TCHEA1 database, with experimental results have shown that the calculations significantly underestimate the temperature range of stability of the phase [27][28][29].…”

Section: Introductionmentioning

confidence: 99%

“…It has been well established that Cr is the main forming element in the CrMnFeCoNi system and as such promotes the formation of the phase [13,14,28,[36][37][38][39][40][41]. In addition, systematic studies of the effect of Mn and Ni have recently been carried out, which assessed the phase stability following long-term exposures at temperatures between 500 and 900˚C [27,29]. This is the temperature range in which second phase precipitates have been observed in the equiatomic alloy [9,10].…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, to elucidate the role of Co on phase equilibria in the CrMnFeCoxNi system, this manuscript presents a systematic study of the phase equilibria of three alloys, where the atomic ratio was x = 0, 0.5, 1.5. All of the alloys were homogenised just below their solidus temperatures prior to long duration exposures of at least 1000 h at 500, 700 and 900˚C; the temperature range in which phase decomposition has been shown to occur in other alloys within the CrMnFeCoNi system [9,10,19,27].…”

Section: Introductionmentioning

confidence: 99%

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Effect of Co on the phase stability of CrMnFeCoxNi high entropy alloys following long-duration exposures at intermediate temperatures

2019

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The effect of Co on the phase stability of the CrMnFeCoxNi family of alloys, where the atomic ratio x = 0, 0.5, 1.5, has been experimentally established following 1000 hour heat treatments at 700 and 900˚C and up to 5000 hours at 500˚C. All the alloys were single phase fcc in the homogenised condition, except for CrMnFeNi which also contained bcc precipitates that remained present following exposures at 900˚C and 700˚C. The exposures at 900˚C and 700˚C also resulted in the formation of phase precipitates in the CrMnFeNi and CrMnFeCo0.5Ni alloys but not in the CrMnFeCo1.5Ni alloy. These data, in conjunction with results previously published in the literature, conclusively establish that Co stabilises the fcc matrix at elevated temperatures. However, at 500˚C, further bulk decomposition in the CrMnFeNi alloy was observed and produced a fine-scale intergrowth of a NiMn L10 phase and CrFe phase. Grain boundary precipitates were also observed following exposure at 500˚C in the CrMnFeCo0.5Ni and CrMnFeCo1.5Ni alloys. Four different phases were observed on the grain boundaries of the CrMnFeCo0.5Ni alloy (Cr carbide, , FeCo B2 and NiMn L10), whilst only two phases were found on the grain boundaries of the CrMnFeCo1.5Ni alloy (Cr carbide and NiMn L10). The experimental observations facilitated an assessment of the fidelity of current thermodynamic predictions of phase equilibria. All the phases predicted were observed experimentally and the stability fitted the experimental observations well. However, at lower temperatures, thermodynamic predictions were less consistent with experimental observations, underpredicting the extent of the B2 phase field and failing to predict the formation of the L10 phase.

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Inter‐Dependency Relationships in High‐Entropy Alloys: Phase Stability Criteria

2019

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In high‐entropy alloys (HEAs), the thermodynamics govern alloy formation, phase stability, and overall phase‐transition characteristics. Over the past decade, many thermodynamic parameters have been proposed for predicting the stability of HEA systems. Herein, analysis of these parameters are carried out carefully with the available data from the literature. It is found that all these parameters are not fully independent from each other and there exists a bridge of interconnection between them. Herein, inter‐dependency relationships between the thermodynamic parameters are derived for predicting the stability of solid solution in HEAs. It is found that parameters with large and complex equations are not essentially required; instead the simple parameters ϕ, Ω, and δ are sufficient for predicting the stability of HEA systems.

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On the prediction and the formation of the sigma phase in CrMnCoFeNix high entropy alloys

Cited by 70 publications

References 35 publications

Nitrogen Interstitial Alloying of CoCrFeMnNi High Entropy Alloy through Reactive Powder Milling

Nitrogen Interstitial Alloying of CoCrFeMnNi High Entropy Alloy through Reactive Powder Milling

Effect of Co on the phase stability of CrMnFeCoxNi high entropy alloys following long-duration exposures at intermediate temperatures

Inter‐Dependency Relationships in High‐Entropy Alloys: Phase Stability Criteria

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