Density Functional Theory of New Double “A” Layer MAX Phase V2Ga2C under High Pressure
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摘要: 基于密度泛函理论的第一性原理,研究了压强对双“A”层MAX相V2Ga2C晶体结构、弹性和电子性质的影响,并利用玻恩稳定准则预测了V2Ga2C力学稳定状态下的压强范围。计算结果表明:在0~70 GPa下,V2Ga2C的晶体结构处于力学稳定状态;随着压强的增大,V2Ga2C的晶格常数和体积均有不同程度的缩小,a轴随压强的增大收缩得最快,晶胞体积收缩了24%左右;随着压强的增加,V2Ga2C材料的维氏硬度从0 GPa压强下的18.23 GPa减小为70 GPa压强下的2.30 GPa,在20.15 GPa时从脆性材料转变为韧性材料;V2Ga2C的态密度和能带结构等电子性质随压强的变化较小,即压强对V2Ga2C的电子性质影响不大。Abstract: The structural, elastic and electronic properties of double “A” layer MAX phase V2Ga2C under high pressure were studied by the first-principles calculations of density functional theory, and the stable state of V2Ga2C was predicted by using the Born stability criteria. The results show that V2Ga2C crystal structure at the state of mechanical stability within the pressure range of 0–70 GPa. With the increase of pressure, the lattice parameters and volumes of V2Ga2C decreased. V2Ga2C is more compressible in the a-axis direction than c-axis direction, and the volume shrinks by about 24%. With increasing pressure, Vickers hardness of V2Ga2C material decreased from 18.23 GPa (0 GPa) to 2.30 GPa (70 GPa), and from brittle material transform into ductile material at 20.15 GPa. With the change of pressure, the electronic properties have changed slightly such as density of states and band structures, which have almost no effect on the electronic properties of V2Ga2C.
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Key words:
- MAX phase /
- V2Ga2C /
- high pressure /
- mechanical stability /
- elastic property /
- electronic property
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图 2 V2Ga2C的相对晶格参数和相对体积随压强的变化
Figure 2. Pressure dependence of relative lattice parameters and relative unit cell volume for V2Ga2C
图 5 不同压强下V2Ga2C的能带结构
Figure 5. Pressure dependence of electronic band structures for V2Ga2C
表 1 不同压强下V2Ga2C的弹性常数
Table 1. Pressure dependences of elastic constants for V2Ga2C
Pressure/GPa C11/GPa C33/GPa C44/GPa C12/GPa C13/GPa 0 275.07 309.04 88.92 65.69 48.31 10 325.89 437.85 103.70 79.38 101.23 20 392.18 492.57 112.70 113.70 122.66 30 475.27 582.90 99.80 176.94 174.81 40 462.17 636.80 103.00 156.69 180.10 50 524.87 696.25 51.41 228.45 221.66 60 558.67 743.34 29.53 220.05 219.34 70 640.36 854.90 4.53 280.99 275.36 80 618.66 892.67 −84.84 305.13 305.24 
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[1] WAI-YIM C, YUXIANG M, ARYAL S, et al. Intrinsic mechanical properties of 20 MAX-phase compounds [J]. Journal of the American Ceramic Society, 2013, 96(7): 2292–2297. doi: 10.1111/jace.12376 [2] BARSOUM M W. The M N+1AXN phases: a new class of solids [J]. Progress in Solid State Chemistry, 2000, 28(1/2/3/4): 201–281. doi: 10.1016/S0079-6786(00)00006-6 [3] BARSOUM M W, BRODKIN D, EL-RAGHY T. Layered machinable ceramics for high temperature applications [J]. Scripta Materialia, 1997, 36(5): 535–541. doi: 10.1016/S1359-6462(96)00418-6 [4] SONG G M, LI S B, ZHAO C X, et al. Ultra-high temperature ablation behavior of Ti2AlC ceramics under an oxyacetylene flame [J]. Journal of the European Ceramic Society, 2011, 31(5): 855–862. doi: 10.1016/j.jeurceramsoc.2010.11.035 [5] JIAO Z Y, MA S H, WANG T X. High-pressure phase stability, mechanical properties and bonding characteristics of Ti4GeC3 compound [J]. Solid State Sciences, 2015, 39: 97–104. doi: 10.1016/j.solidstatesciences.2014.12.003 [6] HOPFELD M, GRIESELER R, VOGEL A, et al. Tribological behavior of selected M n+1AXn phase thin films on silicon substrates [J]. Surface and Coatings Technology, 2014, 257: 286–294. [7] HU C F, LAI C C, TAO Q, et al. Mo2Ga2C: a new ternary nanolaminated carbide [J]. Chemical Communications, 2015, 51(30): 6560–6563. doi: 10.1039/C5CC00980D [8] THORE A, DAHLQVIST M, ALLING B, et al. Phase stability of the nanolaminates V2Ga2C and (Mo1- xVx)2Ga2C from first-principles calculations [J]. Physical of Materials Science, 2016, 51(18): 12682–12688. [9] FASHANDI H, LAI C C, DAHLPVIST M, et al. Ti2Au2C and Ti3Au2C2 formed by soild state reaction of gold with Ti2AlC and Ti3AlC2 [J]. Chemical Communications, 2017, 53(69): 9554–9557. doi: 10.1039/C7CC04701K [10] THORE A, DAHLQVIST M, ALLING B, et al. Temperature dependent phase stability of nanolaminated ternaries from first-principles calculations [J]. Computational Materials Science, 2014, 91(2): 251–257. [11] 金森, 周爱国, 胡前库, 等. 三元碳化物Mo2Ga2C及其二维衍生物的研究进展 [J]. 硅酸盐通报, 2020, 39(3): 866–872.JIN S, ZHOU A G, HU Q K, et al. Progress in ternary carbide Mo2Ga2C and its two-dimensional derivatives [J]. Bulletin of the Chinese Ceramic Society, 2020, 39(3): 866–872. [12] CLARK S J, SEGALL M D, PICKARD C J, et al. First principles methods using CASTEP [J]. Zeitschrift für Kristallographie-Crystalline Materials, 2005, 220(5): 567–570. [13] SEGALL M D, LINDAN P J D, PROBERT M J, et al. First-principles simulation: ideas, illustrations and the CASTEP code [J]. Journal of Physics Condensed Matter, 2002, 14(11): 2717–2744. doi: 10.1088/0953-8984/14/11/301 [14] CHEN Z Y, ALBRIGHT P C, SENGERS J V. Crossover from singular critical to regular classical thermodynanic behavior of fluids [J]. Physical Review A, 1990, 41(6): 3161–3177. doi: 10.1103/PhysRevA.41.3161 [15] PERDEW J P, BURKE K, ERNZERHOF M. Generalized gradient approximation made simple [J]. Physical Review Letters, 1996, 77(18): 3865. doi: 10.1103/PhysRevLett.77.3865 [16] KRESSE G, JOUBERT D. From ultrasoft pseudopotentials to the projector augmented-wave method [J]. Physical Review B, 1999, 59(3): 1758–1775. doi: 10.1103/PhysRevB.59.1758 [17] PUGH S F. XCII. Relations between the elastic moduli and the plastic properties of polycrystalline pure metals [J]. Philosophical Magazine, 1954, 45(367): 823–843. [18] HUANG X, NAUMOV I I, RABE K M. Phonon anomalies and elastic constants of cubic NiAl from first principles [J]. Physical Review B, 2004, 70(6): 064301. [19] HILL R. The elastic behaviour of a crystalline aggregate [J]. Proceedings of the Physical Society, 1952, 65(5): 349–354. doi: 10.1088/0370-1298/65/5/307 -
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