A Combinatorial Approach for Assessing the Magnetic Properties of High Entropy Alloys: Role of Cr in AlCoxCr1–xFeNi

Borkar, Tushar; Chaudhary, Varun; Gwalani, Bharat; Choudhuri, Deep; Mikler, C. V.; Soni, Vishal; Alam, Talukder; Ramanujan, R.V.; Banerjee, Rajarshi

doi:10.1002/adem.201700048

Cited by 102 publications

(54 citation statements)

References 47 publications

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“…al on FeCoCrNi alloys. [7][8][9] The multiple similarly sized atoms mixed in relatively equiatomic amounts in these alloys lead to a 2 nd order magnetic transition, which is broadened due to the distributed exchange interactions arising from the disorder, [10][11][12][13][14] and allows Tc tuning and control of the refrigeration capacity, which leads to a broader transition range than seen in traditional alloys. This is a novel approach to increasing the refrigeration capacity of a magnetocaloric material that does not rely on physical processing (ball milling, cold rolling, etc) to broaden the temperature range.…”

Section: Introductionmentioning

confidence: 99%

Mössbauer analysis of compositional tuning of magnetic exchange interactions in high entropy alloys

et al. 2019

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We measured the change in the average hyperfine field strength of several high entropy alloys in relation to small compositional deviations from the equiatomic alloy, FeCoNiCuMn. Mössbauer spectra of four psuedo-binary systems, in which Mn content is increased and another element was decreased in equal measure, reveal several discrete peaks in the hyperfine field distribution that show evidence of the discrete exchange interactions between magnetic elements in the alloy. A simple linear regression modelling the perturbation of the average hyperfine field when the composition is altered calculates the contribution of each atom to the overall average. The average hyperfine field is linear with Tc, so these values allow us to estimate Tc for alloys with more complex compositional variation within the window of linearity (<24% Mn based on other alloys). The results were confirmed experimentally by calculating Tc of two new alloys, Fe19Co20Ni19Cu19Mn23 and Fe19Co20Ni19Cu20Mn22.

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Section: Introductionmentioning

confidence: 99%

Mössbauer analysis of compositional tuning of magnetic exchange interactions in high entropy alloys

et al. 2019

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“…The work combined experiments with DFT calculations to determine the balance between the surface and interfacial energies of the observed phases, which is particularly useful in elucidating the complex architectures of HEAs containing more than four phases. Since greater compositional diversity and structural complexity have been the tendency, we conclude the relationship between elements and phase numbers of HEAs based on the large numbers of reports, which is illustrated in Figure 9,13,25,63–75. It shows that the compositions of HEAs reach up to eight elements, and the number of phases achieves four.…”

Section: Phase Structure Of Heasmentioning

confidence: 84%

“…Research has shown that HEAs could get fine soft magnetic properties with high magnetization and low coercivity by selecting suitable elements and compositions. Banerjee et al explored the role of Cr in AlCo x Cr 1− x FeNi (0 ≤ x ≤ 1) to study the magnetic properties 70. The hysteresis loops for AlCo x Cr 1− x FeNi are illustrated in Figure a.…”

Section: Property Adjusting Of Phase Engineered Heasmentioning

confidence: 99%

Section: Property Adjusting Of Phase Engineered Heasmentioning

confidence: 99%

“…Additionally, Dolinšek et al reported that the volume fraction of FCC bulky dendrites could decide the ratio of the ferromagnetic magnetization versus the superparamagnetic magnetization 155. Banerjee et al discovered that the spinodal decomposition reduced the ferromagnetism and lowered the temperature of the ferromagnetic–paramagnetic transition 70. In addition to the tuning strategies mentioned above, other methods could adjust the magnetic properties effectively as well.…”

Section: Property Adjusting Of Phase Engineered Heasmentioning

confidence: 99%

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Phase Engineering of High‐Entropy Alloys

et al. 2020

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High‐entropy alloys (HEAs) are based on five or more principal elements with equal or nearly equal molar fractions and possess many significant advantages over traditional alloys, including high strength and hardness, excellent corrosion resistance, outstanding thermal stability, and irradiation resistance. Phase structure plays a vital role in determining the property of HEAs. For further enhancing the performance of HEAs in various application fields, a controllable synthesis with desired phases is required. In this review, the diverse phase structures of HEAs and the related properties are first introduced. Then, alternative tuning strategies to promote the desired phase structure of HEAs are focused upon. Property adjusting of phase‐engineered HEAs is also discussed in depth. Lastly, some insights into the challenges and future prospects in this rapidly emerging research field are provided.

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Review of the Design of Titanium Alloys with Low Elastic Modulus as Implant Materials

Liang

2020

Adv Eng Mater

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A Combinatorial Approach for Assessing the Magnetic Properties of High Entropy Alloys: Role of Cr in AlCo_xCr_1–xFeNi

Cited by 102 publications

References 47 publications

Mössbauer analysis of compositional tuning of magnetic exchange interactions in high entropy alloys

Mössbauer analysis of compositional tuning of magnetic exchange interactions in high entropy alloys

Phase Engineering of High‐Entropy Alloys

Review of the Design of Titanium Alloys with Low Elastic Modulus as Implant Materials

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