Analysis of Carbides in Multi-component Cast Iron Design Based on High Entropy Alloys Concepts

Pasini, W. M.; Bellé, M. R.; Pereira, L.; do Amaral, R.F.; Barcellos, V. K. de

doi:10.1590/1980-5373-MR-2020-0398

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Article • Mat. Res. 24 (2) • 2021 • https://doi.org/10.1590/1980-5373-MR-2020-0398 copy

Analysis of Carbides in Multi-component Cast Iron Design Based on High Entropy Alloys Concepts

Authorship SCIMAGO INSTITUTIONS RANKINGS

Abstract

Nowadays, the concept of high entropy alloys (HEAs) has expanded the limits of metallurgy and high-quality metallurgical HEAs ingots have already been successfully obtained on an industrial scale. High Chromium Cast Irons (HCCI) and Multi-Component Cast Irons (MCCI) are known to be a useful material for applications when abrasion resistance is required. Inspired by the concepts of high-entropy alloys, a base HCCI was modified, by adding other carbide-forming elements, at concentrations higher than what is currently used, in order to develop a new class of white cast iron, High Entropy White Cast Iron (HEWCI). The characterization of carbides precipitated during the HEWCI solidification was performed by scanning electron microscopy, energy dispersive spectroscopy, electron backscattered diffraction (SEM/EDS/EBSD) and X-ray diffraction (XRD). With the characterization techniques employed, the as-cast microstructure obtained of HEWCI is composed of approximately 50% of austenite matrix and 50% of different types of carbides, MC, M₇C₃ and M₂C carbides.

Keywords:
High entropy alloys; High Chromium Cast Irons; Multi-component Cast Irons; Carbide-forming elements

	C	Cr	Mo	V	Mn	Si	Co	Nb	Fe	ΔS_conf (*)
%Wt	3.45	21.4	11.15	7.3	6.3	1.8	2.0	0.6	45.9	-
%At	14.4	20.6	5.8	7.1	5.7	3.1	1.7	0.3	41.3	-1.68R

	Austenite	MC	M₇C₃	M₂C	Zero solutions
Phase Fraction (%) average	47.4 ±1.5	8.7±0.6	31.6±1.5	7.3±0.9	5.1±0.5
Morphology	Dentritic	Dendritic	Rod-Like	Fibrous
	Eutectic	Chunky	Blade-Like

Alloy Composition [%wt]	V [%wt]	Temperature [°C]	Ref
Fe-3C-5Cr-2Mo-5Co	5	1315	²²22 Liu S, Zhou Y, Xing X, Wang J, Ren X, Yang Q. Growth characteristics of primary M7C3 carbide in hypereutectic Fe-Cr-C alloy. Sci Rep. 2016;6(1):32941.
Fe-3C-5Cr-2Mo-5Co	9	1380	²²22 Liu S, Zhou Y, Xing X, Wang J, Ren X, Yang Q. Growth characteristics of primary M7C3 carbide in hypereutectic Fe-Cr-C alloy. Sci Rep. 2016;6(1):32941.
Fe-4C-5Cr-6Mo-5W	5	1385	²¹21 Nagase T, Kakeshita T, Matsumura K, Nakazawa K, Furuya S, Ozoe N, et al. Development of Fe-Co-Cr-Mn-Ni-C high entropy cast iron (HE cast iron) available for casting in air atmosphere. Mater Des. 2019;184:108172.
Fe-4C-5Cr-2Mo-2W	5	1385	²¹21 Nagase T, Kakeshita T, Matsumura K, Nakazawa K, Furuya S, Ozoe N, et al. Development of Fe-Co-Cr-Mn-Ni-C high entropy cast iron (HE cast iron) available for casting in air atmosphere. Mater Des. 2019;184:108172.
Fe-3C-5Mo-5W	10	1350	⁴4 Matsubara Y, Sasaguri N, Shimizu K, Kon Yu S. Solidification and abrasion wear of white cast irons alloyed with 20% carbide forming elements. Wear. 2001;250-251(1-12):502-10.

Temperature	Propable phases transformations
<1300°C	L₁ — MC_{(pro-eutectic)}+L₂
1286°C	L₂— M₇C_{3(pro-eutectic)}+L₃
1187°C	L₃ — γ + M₇C_3(eutectic) + L₄
1156°C	L₄ — γ + M₂C

		C	Cr	Mo	Nb	V	Mn	Si	Fe
MC proeutectic	Min	46.95	4.73	3.94	2.56	26.97	-	-	0.57
MC proeutectic	Max	56.97	7.70	5.98	5.93	35.71	-	-	1.05
M₇C₃ proeutectic	Min	36.13	29.51	2.06	-	8.73	3.90	-	17.36
M₇C₃ proeutectic	Max	37.96	30.57	2.19	-	9.33	4.34	-	17.68
M₇C₃ eutectic	Min	35.97	26.27	3.24	-	6.55	4.74	-	18.00
M₇C₃ eutectic	Max	40.56	28.40	4.08	-	7.74	5.33	-	19.32
M₂C eutectic	Min	24.22	11.32	9.40	-	2.00	6.74	6.46	34.04
M₂C eutectic	Max	26.88	12.80	10.41	-	2.59	7.58	7.27	36.80

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