Theoretical investigation on the stability, mechanical and thermal properties of the newly discovered MAB phase Cr4AlB4

doi:10.1016/j.jmst.2019.01.017

摘要/Abstract

Abstract:

The nanolaminated MAB phases have attracted great research interests in recent years due to their similarities to MAX phases, which display both metallic and ceramic-like properties. In the present work, a newly discovered MAB phase Cr₄AlB₄ was investigated by first principles calculations. Energy evaluations indicate that Cr₄AlB₄ can be synthetized in Al lean condition, which can further transform to Cr₂AlB₂ in Al rich condition. The full set of elastic properties and their dependences on temperature, ideal strengths under different tensile and shear deformations, and thermal expansions of Cr₄AlB₄ were predicted. The results reveal that the properties of Cr₄AlB₄ are dominated by the layered crystal structure and weak bonding nature between Al and Cr₂B₂ layers, including low elastic stiffness and large thermal expansion along [010] direction (the stacking direction of Al and Cr₂B₂ layers), low shear resistances in (010) plane, and preferentially cleavage along and/or shear in (010) plane. Therefore, it suggests that Cr₄AlB₄ displays similar mechanical properties to MAX phases, including readily machinable, thermal shock resistant, and damage tolerant. In combination with the fact that Cr, Al and B all can form dense oxides to protect the material from further oxidation, Cr₄AlB₄ is regarded as a promising high temperature ceramic.

Key words: MAB phase, Cr₄AlB₄, First-principles, Mechanical properties, Thermal properties

. [J]. 材料科学与技术, 2020, 39(0): 161-166.

Fu-Zhi Dai, Haiming Zhang, Huimin Xiang, Yanchun Zhou. Theoretical investigation on the stability, mechanical and thermal properties of the newly discovered MAB phase Cr₄AlB₄[J]. J. Mater. Sci. Technol., 2020, 39(0): 161-166.

图/表 7

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Compounds	Cr₂AlB₂	Cr₄AlB₄	Cr₆AlB₆
space group	Cmmm	Immm	Cmmm
Z	2	2	2
Experimental lattice parameters [1,25] Lattice constants (Å)	a = 2.9373	a = 2.9343
	b = 11.0513	b = 18.8911
	c = 2.9675	c = 2.9734
Atomic positions		Cr1 4g(0,0.2937,0)
	Cr 4i(0,0.1474,0)	Cr2 4h(0.5,0.5860,0)
	Al 2c(0,0.5,0.5)	Al 2b(0,0.5,0.5)
	B 4j(0,0.2941,0.5)	B1 4h(0,0.3840,0.5)
		B2 4g(0.5,0.6646,0.5)
Geometry optimized lattice parameters Lattice constants (Å)	a = 2.9352	a = 2.9321	a = 2.9715
	b = 11.0160	b = 18.9116	b = 21.3894
	c = 2.9533	c = 2.9522	c = 2.9610
Atomic positions		Cr1 4g(0,0.2926,0)	Cr1 4i(0.5,0.0608,0)
	Cr 4i(0,0.1468,0)	Cr2 4h(0.5,0.5866,0)	Cr2 4i(0,0.1459,0)
	Al 2c(0,0.5,0.5)	Al 2b(0,0.5,0.5)	Cr3 4j(0.5,0.2069,0.5)
	B 4j(0,0.2940,0.5)	B1 4h(0,0.3813,0.5)	Al 2d(0,0,0.5)
		B2 4g(0.5,0.6709,0.5)	B1 4j(0,0.0837,0.5)
			B2 4j(0.5,0.1207,0.5)
			B2 4j(0,0.2313,0.5)

Compounds	Cr₂AlB₂	Cr₄AlB₄	Cr₆AlB₆
space group	Cmmm	Immm	Cmmm
Z	2	2	2
Experimental lattice parameters [1,25] Lattice constants (Å)	a = 2.9373	a = 2.9343
	b = 11.0513	b = 18.8911
	c = 2.9675	c = 2.9734
Atomic positions		Cr1 4g(0,0.2937,0)
	Cr 4i(0,0.1474,0)	Cr2 4h(0.5,0.5860,0)
	Al 2c(0,0.5,0.5)	Al 2b(0,0.5,0.5)
	B 4j(0,0.2941,0.5)	B1 4h(0,0.3840,0.5)
		B2 4g(0.5,0.6646,0.5)
Geometry optimized lattice parameters Lattice constants (Å)	a = 2.9352	a = 2.9321	a = 2.9715
	b = 11.0160	b = 18.9116	b = 21.3894
	c = 2.9533	c = 2.9522	c = 2.9610
Atomic positions		Cr1 4g(0,0.2926,0)	Cr1 4i(0.5,0.0608,0)
	Cr 4i(0,0.1468,0)	Cr2 4h(0.5,0.5866,0)	Cr2 4i(0,0.1459,0)
	Al 2c(0,0.5,0.5)	Al 2b(0,0.5,0.5)	Cr3 4j(0.5,0.2069,0.5)
	B 4j(0,0.2940,0.5)	B1 4h(0,0.3813,0.5)	Al 2d(0,0,0.5)
		B2 4g(0.5,0.6709,0.5)	B1 4j(0,0.0837,0.5)
			B2 4j(0.5,0.1207,0.5)
			B2 4j(0,0.2313,0.5)

	c₁₁	c₂₂	c₃₃	c₄₄	c₅₅	c₆₆	c₁₂	c₂₃	c₃₁
Cr₄AlB₄	538	490	477	173	219	176	116	124	122
Cr₂AlB₂ [10]	502	408	430	134	186	126	101	114	116
Ti₂AlC [10]	304	304	274	119	119	127	50	57	57
Ti₃AlC₂ [10]	355	355	292	123	123	142	71	68	68
	E_x	E_y	E_z	B	G	E	ν	G/B
Cr₄AlB₄	491	444	429	247	189	452	0.196	0.764
Cr₂AlB₂ [10]	445	354	371	222	154	376	0.217	0.696
Ti₂AlC [10]	287	287	255	135	120	278	0.157	0.889
Ti₃AlC₂ [10]	334	334	276	157	130	306	0.176	0.828

	c₁₁	c₂₂	c₃₃	c₄₄	c₅₅	c₆₆	c₁₂	c₂₃	c₃₁
Cr₄AlB₄	538	490	477	173	219	176	116	124	122
Cr₂AlB₂ [10]	502	408	430	134	186	126	101	114	116
Ti₂AlC [10]	304	304	274	119	119	127	50	57	57
Ti₃AlC₂ [10]	355	355	292	123	123	142	71	68	68
	E_x	E_y	E_z	B	G	E	ν	G/B
Cr₄AlB₄	491	444	429	247	189	452	0.196	0.764
Cr₂AlB₂ [10]	445	354	371	222	154	376	0.217	0.696
Ti₂AlC [10]	287	287	255	135	120	278	0.157	0.889
Ti₃AlC₂ [10]	334	334	276	157	130	306	0.176	0.828

Theoretical investigation on the stability, mechanical and thermal properties of the newly discovered MAB phase Cr₄AlB₄

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