Facile preparation and magnetic study of amorphous Tm-Fe-Co-Ni-Mn multicomponent alloy nanofilm

Yao, Chenzhong; Wei, Bohui; Zhang, Peng; Lu, Xihong; Liu, Peng; Tong, Yexiang

doi:10.1016/s1002-0721(10)60418-8

Cited by 34 publications

(14 citation statements)

References 25 publications

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“…By breaking through the traditional "single-element" base idea, the compositionally complex HEAs greatly widen the alloy design space for tailoring phase structure, stacking-fault energy, and associated deformation mechanisms in alloys, thereby significantly stimulating the rapid synthesis of more and more advanced materials with desirable mechanical properties. [5][6][7][8][9][10][11][12][13] Among them, the single-phase HEAs with the face-centered cubic (FCC) structure initially attract great interest among the material community due to their many attractive mechanical properties, such as the excellent tensile ductility and fracture toughness at cryogenic temperatures. 5,[14][15][16][17] However, the low strengths at ambient and elevated temperatures make them inadequate for lots of engineering applications.…”

Section: Introductionmentioning

confidence: 99%

L1₂-strengthened high-entropy alloys for advanced structural applications

et al. 2018

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Section: Introductionmentioning

confidence: 99%

L1₂-strengthened high-entropy alloys for advanced structural applications

et al. 2018

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“…Since it does not require the complex equipment and expensive raw materials, electrochemical deposition provides a possibility of the low-cost synthesis of HEA films. Furthermore, through altering the deposition parameters, electrodeposition can easily control the composition, morphology, and thickness of the films [59][60][61]. Yao et al [40] prepared the amorphous BiFeCoN-iMn HEA films by potentiostatic electrodeposition.…”

Section: Electrochemical Depositionmentioning

confidence: 99%

Microstructures and properties of high-entropy alloy films and coatings: a review

Liu

Liaw

2018

Materials Research Letters

424

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In the past 14 years, as a branch of high-entropy alloy (HEA) materials, HEA films and coatings have exhibited the attractive and unique properties, relative to the conventional film and coating materials. The recent research and development of HEA films and coatings are reviewed in this paper. At first, the basic concept of HEAs films and coatings are introduced. Then, their preparation technologies, microstructures and appealing properties are summarized. Moreover, the possible reasons and design criteria for achieving the excellent properties are discussed. Finally, the suggested future research work for the HEA films and coatings are outlined. IMPACT STATEMENT Preparation technologies, microstructures, and properties of HEA films and coatings are reviewed in this paper. The design criteria and suggested research directions are further discussed and proposed.

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“…On the basis of the development of HEAs, HEA films are frequently investigated because of their mechanical and thermal properties. Many researchers have prepared HEA films by using various methods, such as magnetron sputtering [4][5][6][7][8][9][10][11][12], laser cladding [13][14][15], electrochemical deposition [16], arc thermal spraying [17], cold spraying [18], electron beam evaporation deposition [19], and plasma cladding [20]. At present, laser cladding and magnetron sputtering are commonly used by researchers to obtain films with excellent physical properties.…”

Section: Introductionmentioning

confidence: 99%

Oxidation Behavior and Structural Transformation of (CrTaTiVZr)N Coatings

Chang

Liang

2020

Coatings

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(CrTaTiVZr)N coatings were prepared on Si substrates through the reactive magnetron sputtering system to investigate the oxidation behaviors and structural evolution of the coatings at different annealing temperatures in air. The (CrTaTiVZr)N coating had a face-centered cubic structure with an oxidation temperature of up to 300 °C, but its surface changed into the amorphous oxide phase and then into the rutile TiO2 phase when the annealing temperature was increased to 500 °C. The rutile TiO2 phase continued to grow, and an additional solid solution phase of body-centered tetragonal I41/amd was formed at annealing temperatures beyond 600 °C. The high annealing temperature promoted the oxidation to progress along the thickness direction and synergistically developed the porosity. As a result, the hardness and the electrical performance of the coating deteriorated. The hardness decreased from 34.30 GPa to 1.52 GPa, and the electrical resistivity increased from 142 µΩ·cm to 17.5 Ω·cm.

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Facile preparation and magnetic study of amorphous Tm-Fe-Co-Ni-Mn multicomponent alloy nanofilm

Cited by 34 publications

References 25 publications

L1₂-strengthened high-entropy alloys for advanced structural applications

L1₂-strengthened high-entropy alloys for advanced structural applications

Microstructures and properties of high-entropy alloy films and coatings: a review

Oxidation Behavior and Structural Transformation of (CrTaTiVZr)N Coatings

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Facile preparation and magnetic study of amorphous Tm-Fe-Co-Ni-Mn multicomponent alloy nanofilm

Cited by 34 publications

References 25 publications

L12-strengthened high-entropy alloys for advanced structural applications

L12-strengthened high-entropy alloys for advanced structural applications

Microstructures and properties of high-entropy alloy films and coatings: a review

Oxidation Behavior and Structural Transformation of (CrTaTiVZr)N Coatings

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L1₂-strengthened high-entropy alloys for advanced structural applications

L1₂-strengthened high-entropy alloys for advanced structural applications