First-principles calculation of mechanical properties of Fe,Co and Ni doped 3C-SiC

doi:10.3969/j.issn.1001-1935.2021.06.004

Abstract

Abstract:

SiC is widely used in the field of refractories because of its excellent mechanical properties.The synthesis of SiC powder by catalytic reaction has a bright future.However,it is difficult to separate the catalysts,which act as impurities.While the influence of catalysts on the properties of SiC has not been studied.Therefore,the first-principles plane-wave pseudopotential method was used to study the catalysts (Fe,Co and Ni) and the doping concentration (1.56%,3.125%,6.25%,and 12.5%,by atom) on the thermodynamic properties,the mechanical properties and the density of states (DOS) of 3C-SiC.The results show that:(1)the structure stability of 3C-SiC crystals doped with Fe,Co and Ni atoms decreases in the order of Fe-SiC,Co-SiC and Ni-SiC.(2)When the Fe doping concentration is 1.56%,compared with the undoped 3C-SiC crystal,the changes of the elasticity modulus,the shear modulus and the Young’s modulus of Fe-SiC are 0.023%,3.57% and 2.77%,and the hardness and the brittleness do not change obviously,and DOS diagram is basically unchanged,which shows that low concentration Fe doping has negligible effect on the mechanical properties of 3C-SiC system.Therefore,SiC powder prepared by catalytic reaction method with Fe as the catalyst can be used in the field of refractories in theory.

Key words: silicon carbide, Fe,Co and Ni, catalytic reaction method, first-principles calculation, mechanical properties

摘要：

碳化硅以其优异的性能被广泛应用于耐火材料领域。催化反应法合成碳化硅粉体的前景广阔,但加入的催化剂作为杂质却难以分离,而催化剂对产物碳化硅性能的影响尚缺乏研究。采用第一性原理平面波赝势法研究了催化剂种类(Fe、Co及Ni)和元素掺杂浓度(x,1.56%、3.125%、6.25%、12.5%)对3C-SiC热力学性质、力学性能、电子态密度等的影响。结果表明:1)Fe、Co及Ni掺杂3C-SiC晶体的结构稳定性由大到小依次为Fe-SiC、Co-SiC、Ni-SiC;2)当Fe元素掺杂浓度为1.56%(x)时,与未掺杂3C-SiC晶体相比,Fe-SiC体系体弹性模量值变化量为0.023%,剪切模量和杨氏模量变化量为3.57%与2.77%,硬度值和脆韧性基本未发生明显变化,态密度图也基本不变,说明低浓度Fe元素掺杂基本不影响3C-SiC体系的力学性能。因此,用Fe作催化剂,采用催化反应法制备的碳化硅粉体理论上是可以应用于耐火材料领域的。

关键词: 碳化硅, Fe、Co及Ni, 催化反应法, 第一性原理计算, 力学性能

CLC Number:

TQ175.1

Shan Jingyi, Huang Zhenxia, Wang Junkai, Li Tao, Zhou Xuan, Xing Yingying. First-principles calculation of mechanical properties of Fe,Co and Ni doped 3C-SiC[J]. Refractories, 2021, 55(6): 476-482.

闪静祎, 黄珍霞, 王军凯, 李韬, 周轩, 邢盈盈. Fe、Co及Ni单掺3C-SiC力学性能的第一性原理计算[J]. 耐火材料, 2021, 55(6): 476-482.

Figures/Tables 6

References 35

[1]	昝文宇, 马北越. 高纯SiC微粉制备进展[J]. 耐火材料, 2021, 55(2):161-168.
[2]	王玉霞, 何海平, 汤洪高. 宽带隙半导体材料SiC研究进展及其应用[J]. 硅酸盐学报, 2002, 30(3):372-381.
[3]	艾俊迪, 余超, 董博, 等. 添加Al粉对反应烧结碳化硅性能和结构的影响[J]. 耐火材料, 2021, 55(1):51-55.
[4]	王晓峰, 李欣, 刘坤, 等. 用SiO₂微粉制备碳化硅粉体的研究[J]. 耐火材料, 2020, 54(2):112-117.
[5]	钟香崇, 赵海雷. 氧化物-非氧化物复合耐火材料高温性能的研究[J]. 耐火材料, 2000, 34(2):63-68.
[6]	孙祥运, 陈浩, 王顺琴, 等. 碳化硅-金刚石陶瓷的制备及其导热性能[J]. 耐火材料, 2021, 55(2):131-134.
[7]	桂明玺. 碳化硅耐火材料的特点和用途[J]. 耐火与石灰, 1999, 24(8):42-47.
[8]	李可琢, 张海军, 苑高千, 等. 聚碳硅烷制备SiC陶瓷研究进展[J]. 耐火材料, 2020, 54(3):260-265.
[9]	曹会彦, 黄志刚, 李杰, 等. 使用6年后干熄炉氮化物结合碳化硅砖的变化[J]. 耐火材料, 2021, 55(4):322-324.
[10]	脱庆运. 浅谈SiC耐火材料在煤气化炉上的应用[J]. 山东化工, 2016, 45(22):112-114.
[11]	WU W, GUI J, WEI S, et al. Si₃N₄-SiCw composites astructural materials for cryogenic application[J]. Journal of the European Ceramic Society, 2016, 36:2667-2672. DOI URL
[12]	WANG Z, SKYBAKMOEN E, GRANDE T. Spent Si₃N₄ bonded SiC sidelining materials in aluminium electrolysis cells[J]. Tms Light Metals, 2009,353-358.
[13]	李金雨, 占华生, 刘淑焕, 等. 垃圾焚烧炉用矾土均质料-碳化硅质抗飞灰附着浇注料的研究[J]. 耐火材料, 2020, 54(3):246-249.
[14]	CHEN J, WANG X G. Variation law of temperature field in synjournal of SiC by carbothermal reduction method[J]. Bulletin of the Chinese Ceramic Society, 2013, 20(5):655-660.
[15]	吕东风, 康剑, 魏恒勇, 等. 非水解溶胶-凝胶法结合碳热还原法制备β-SiC粉体[J]. 耐火材料, 2017, 51(6):438-441.
[16]	CETINKAYA S, EROGLU S. Chemical vapor deposition of C on SiO₂ and subsequent carbothermal reduction for the synjournal of nanocrystalline SiC particles/whiskers[J]. International Journal of Refractory Metals and Hard Materials, 2011, 29(5):566-572. DOI URL
[17]	CHOI H, SEONG H, LEE J, et al. Growth and modulation of silicon carbide nanowires[J]. Journal of Crystal Growth, 2004, 269(2-4):472-478. DOI URL
[18]	戴学刚, 郑国梁, 荣金龙, 等. 等离子体法制备碳化硅超细粉末研究[J]. 化工冶金, 1996(4):310-315.
[19]	郝斌. 微波烧结碳化硅的制备[J]. 材料热处理学报, 2015, 36(5):39-44.
[20]	LU Q, HU J, TANG K, et al. Growth of SiC nanorods at low temperature[J]. Applied Physics Letters, 1999, 75(4):507-509. DOI URL
[21]	王军凯, 韩磊, 黄亮, 等. 催化反应制备碳化硅纳米粉体的密度泛函理论计算及实验研究[J]. 高等学校化学学报, 2017, 38(9):1602-1610.
[22]	CAO L Z, LIU X, ZHAO J Q, et al. Synjournal and photoluminescence of the branching silicon carbide nanowires[J]. Physica E:Low-dimensional Systems and Nanostructures, 2012, 46:57-60. DOI URL
[23]	王军凯, 张远卓, 李赛赛, 等. Fe催化硅藻土碳热还原反应制备3C-SiC及其机理[J]. 材料研究学报, 2018, 32(10):767-774.
[24]	WANG J K, ZHANG Y Z, LI J Y, et al. Catalytic effect of cobalt on microwave synjournal of β-SiC powder[J]. Powder Technology, 2017, 317:209-215. DOI URL
[25]	WANG J K, ZHANG Y Z, ZHANG H J, et al. Low-temperature catalytic synjournal of SiC nanopowder from liquid phenolic resin and diatomite[J]. Advances in Applied Ceramics, 2018, 117(3):147-154. DOI URL
[26]	QIANG X F, LI H J, ZHANG Y L, et al. Synjournal of SiC/SiO₂ nanocables by chemical vapor deposition[J]. Journal of Alloys and Compounds, 2013, 572(1):107-109. DOI URL
[27]	王军凯, 李俊怡, 梁峰, 等. 以酚醛树脂为碳源低温催化反应合成碳化硅粉体[J]. 硅酸盐学报, 2016, 44(12):1798-1804.
[28]	王军凯, 邓先功, 张海军, 等. 以酚醛树脂和硅藻土为原料低温催化反应合成碳化硅粉体[J]. 稀有金属材料与工程, 2018, 47(S1):95-98.
[29]	王军凯, 张远卓, 李俊怡, 等. 微波加热催化反应低温制备β-SiC粉体[J]. 无机材料学报, 2017, 32(7):725-730.
[30]	CLARK S J, SEGALLII M D, PICKARDII C J, et al. First principles methods using castep[J]. Zeitschrift für Kristallographie-Crystalline Materials, 2005, 220(5-6).
[31]	PERDEW J P, BURKE K, ERNZERHOF M, et al. Generalized gradient approximation made simple[J]. Physical Review Letters, 1996, 77(18):3865-3868. DOI URL
[32]	PERDEW J P, YUE W. Accurate and simple density functional for the electronic exchange energy:Generalized gradient approximation[J]. Physical Review B, 1986, 33(12):8800-8802. DOI URL
[33]	VANDERBILT D. Soft self-consistent pseudopotentials in a generalized eigenvalue formalism[J]. Physical Review B Condensed Matter, 1990, 41(11):7892-7895. DOI URL
[34]	VAN CAMP P E, VAN DOREN V E, DEVREESE J T. First-principles calculation of the pressure coefficient of the indirect band gap and of the charge density of C and Si[J]. Physical Review B Condensed Matter, 1986, 34(2):1314-1316. DOI URL
[35]	LU X F, ZHAO T T, GUO X, et al. Electronic structures and optical properties of IV A elements-doped 3C-SiC from density functional calculations[J]. Modern Physics Letters B, 2018, 32(32):1850389. DOI URL

计算体系	a/nm	b/nm	c/nm	生成焓/eV	结合能/eV
SiC	0.436 4	0.436 4	0.436 4	-0.242	-6.916
Fe-SiC	0.873 0	0.873 0	0.873 0	-0.190	-6.866
Co-SiC	0.873 2	0.873 2	0.873 2	-0.182	-6.855
Ni-SiC	0.873 5	0.873 5	0.873 5	-0.175	-6.844

计算体系	a/nm	b/nm	c/nm	生成焓/eV	结合能/eV
SiC	0.436 4	0.436 4	0.436 4	-0.242	-6.916
Fe-SiC	0.873 0	0.873 0	0.873 0	-0.190	-6.866
Co-SiC	0.873 2	0.873 2	0.873 2	-0.182	-6.855
Ni-SiC	0.873 5	0.873 5	0.873 5	-0.175	-6.844

项目	SiC	Fe-SiC	Co-SiC	Ni-SiC
体弹性模量/GPa	212.03	212.08	211.32	210.74
剪切模量/GPa	189.40	182.63	152.70	153.74
杨氏模量/GPa	437.83	425.70	369.18	371.00
泊松比	0.156	0.165	0.209	0.207
硬度	33.15	30.99	22.36	22.71
B/G比值	1.119	1.161	1.384	1.371

项目	SiC	Fe-SiC	Co-SiC	Ni-SiC
体弹性模量/GPa	212.03	212.08	211.32	210.74
剪切模量/GPa	189.40	182.63	152.70	153.74
杨氏模量/GPa	437.83	425.70	369.18	371.00
泊松比	0.156	0.165	0.209	0.207
硬度	33.15	30.99	22.36	22.71
B/G比值	1.119	1.161	1.384	1.371

项目	Fe掺杂浓度(x)/%
项目	0	1.56	3.125	6.25	12.5
体弹性模量/GPa	212.03	212.08	212.08	211.82	211.21
剪切模量/GPa	189.40	182.63	176.41	163.20	140.21
杨氏模量/GPa	437.83	425.70	414.34	389.56	344.71
泊松比	0.156	0.165	0.174	0.193	0.229
硬度	33.15	30.99	29.06	25.21	19.01
B/G比值	1.119	1.161	1.216	1.298	1.514