Electroless Copper Plating on Different Types of Ceramic Particles and Its Effects on Mechanical Properties of Particulate Reinforced Iron Matrix Composites

doi:10.11901/1005.3093.2014.240

Chinese Journal of Materials Research

2015, Vol. 29

Issue (1): 17-24 DOI: 10.11901/1005.3093.2014.240

Current Issue | Archive | Adv Search

Electroless Copper Plating on Different Types of Ceramic Particles and Its Effects on Mechanical Properties of Particulate Reinforced Iron Matrix Composites

Xinjian CAO,Jianfeng JIN(

),Yuebo ZHANG,Yaping ZONG

Key Laboratory for Anisotropy and Texture of Materials, Ministry of Education, Northeastern University, Shenyang 110819, China

Cite this article:

Xinjian CAO,Jianfeng JIN,Yuebo ZHANG,Yaping ZONG. Electroless Copper Plating on Different Types of Ceramic Particles and Its Effects on Mechanical Properties of Particulate Reinforced Iron Matrix Composites. Chinese Journal of Materials Research, 2015, 29(1): 17-24.

Download:

HTML

PDF(5996KB)
Export: BibTeX | EndNote (RIS)

Abstract

Electroless Cu plating process has been studied in order to coat three kind of ceramic particles of different size. It is found that the amount of complexing agent addition in the plating bath should be adjusted corresponding to the size of the coated particles to obtain coatings with acceptable quality. However, all the three kind of ceramic particles show more or less the same behavior during plating. Mechanical properties of the SiCp/Fe、TiNp/Fe and TiCp/Fe composites containing reinforcing particulates with and without Cu coating respectively were measured comparatively. Results show that the mechanical properties of all the three composites with Cu coated reinforcing particles are superior significantly to their counterparts. However the highest enhancement of tensile strength induced by Cu coated particles was observed for the TiNp/Fe composite, but not for the SiCp/Fe composite, which showed the highest tensile strength among the three composites with raw ceramic particles without Cu-coating. It is clear that the defects at the interfaces of particles and matrix should be a determining factor affecting the tensile strength of the composite. Similarly, the larger content of particles with Cu coating in the composite is, the higher enhancement in mechanical properties may be expected. Moreover, microstructure analysis also indicates that the copper coating on particles could effectively avoid the direct contact of particles and reduce defects formed at the interfaces between the particles and matrix.

Key words: composite electroless copper plating particles strengthening mechanical property

Received: 12 May 2014

Fund: *Supported by National Natural Science Foundation of China Nos. 51171040 & U1302272 & 51301035 and High Technology Research and Development Program of China No. 2013AA031601, Northeastern University Young Talent Start-up Funding No.01270021814101/024.

	Service

	E-mail this article
	Add to citation manager
	E-mail Alert
	RSS
	（）
	Articles by authors
	Xinjian CAO
	Jianfeng JIN
	Yuebo ZHANG
	Yaping ZONG

URL:

https://www.cjmr.org/EN/10.11901/1005.3093.2014.240 OR https://www.cjmr.org/EN/Y2015/V29/I1/17

Fig.1 Relationship between deposition rate on the surface of TiN particles with different sizes and the molar ratio of complexing agent against copper salt

Fig.2 SEM image of surface morphology of 5 μm TiN particles before (a) and after copper-coated , the mole ratio of complexing agent against copper salt is 0.5∶1 (b), 0.8∶1 (c) and 1∶1 (d)

Fig.3 SEM image of surface morphology for copper-coated 10 μm TiN particles reduced from the mole ratio of complexing agent against copper salt of (a) 0.65∶1 and (b) 0.8∶1

Table 1 Chemical composition in the plating bath and optimum operating parameters for TiN particles

Fig.4 Comparison of the tensile strength of the composites reinforced by (a) 15% and (b) 20% different types of particles before and after copper coating

Fig.5 Comparison of the elongation of the composites reinforced by (a) 15% and (b) 20% different types of particles with and without copper coating, respectively

Fig.6 Relative density of the composites reinforced by (a) 15% and (b) 20% different types of particles with and without copper coating, respectively

Fig.7 Microstructure of the composite reinforced by 15% TiC particles uncoated (a) and copper-coated (b) and by 20% TiC particles uncoated (c) and copper-coated (d)

Fig.8 SEM image of microstructure (a) of the copper-coated TiC particle reinforced composite and the EDS analysis of different elements (b) Ti (c) Fe (d) Cu

Fig.9 Fracture surface morphology of the composites reinforced by TiC particles before (a) and after (b) copper coating

1	R. Queeney,Wear resistance of WC and VC reinforced tool steel as-sintered composites, Advances in Powder Metallurgy, 2, 77(1990)
2	S. Weber, W. Theisen,Sintering of High Wear Resistant Metal Matrix Composites, Advanced Engineering Materials, 9(3), 165(2007)
3	Z. Mei, Y. Yan, K. Cui,Effect of matrix composition on the microstructure of in situ synthesized TiC particulate reinforced iron-based composites, Materials Letters, 57(21), 3175(2003)
4	B. Song, S. Dong, P. Coddeta, G. Zhou, O. Sheng, H. Liao, C. Coddeta,Microstructure and tensile behavior of hybrid nano-micro SiC reinforced iron matrix composites produced by selective laser melting, Journal of Alloys and Compounds, 579, 415(2013)
5	A. Slipenyuk, V. Kuprin,Properties of P/M processed particle reinforced metal matrix composites specified by reinforcement concentration and matrix-to-reinforcement particle size ratio, Acta Materialia, 54(1), 157(2006)
6	LIU Debao,CUI Chunxiang, Fabrication and Properties of TiN Particle Reinforced Copper Matrix Composites, Chinese Journal of Rare Metals, 28(5), 856(2004)
6	(刘德宝, 崔春翔, TiN颗粒增强铜基复合材料的制备及性能研究, 稀有金属, 28(5), 856(2004))
7	J. Pelleg,Reactions in the matrix and interface of the Fe-SiC metal matrix composite system, Materials Science and Engineering A, 269(1), 225(1999)
8	E. Pagounis, V. K. Lindroos,Processing and properties of particulate reinforced steel matrix composites, Materials Science and Engineering A, 246, 221(1998)
9	WANG Yaomian, ZONG Yaping, ZHUANG Weibin, LI Jie, Effects of content and size of reinforcing particles on mechanical properties of SiCp/Fe Composites processed by dynamic hot press sintering, Materials Science and Technology, 19(1), 47(2011)
9	(王耀勉, 宗亚平, 庄伟彬, 李杰, 增强颗粒含量和尺寸对SiCp/Fe 复合材料性能的影响, 材料科学与工艺, 19(1), 47(2011))
10	W. Zhuang, B.Y. Zong, Y. Wang, Y. Yang,Processing and properties of SiCp/Fe composites by resistance sintering with a novel dynamic temperature control, Journal of Composite Materials, 47(8), 1001(2013)
11	J. Li, B.Y. Zong, Y. Wang, Y. Yang,Experiment and modeling of mechanical properties on iron matrix composites reinforced by different types of ceramic particles, Materials Science and Engineering A, 527(29), 7545(2010)
12	D. Yi, P. Yu, B. Hu, H. Liu, B. Wang, Y. Jiang,Preparation of nickel-coated titanium carbide particulates and their use in the production of reinforced iron matrix composites, Materials and Design, 52, 572(2013)
13	ZHANG Yuebo,ZONG Yaping, CAO Xinjian, ZHANG Long, Effects of Chemical Ni Plating of Reinforcing Particles on Properties of SiCp/Fe Composite, Chinese Journal of Materials Research, 26(5), 483(2012)
13	(张跃波, 宗亚平, 曹新建, 张龙, 碳化硅颗粒化学镀镍对铁基复合材料性能的影响, 材料研究学报, 26(5), 483(2012))
14	M. Tan, Q. Xin, Z. Li, B.Y. Zong,Influence of SiC and Al2O3 particulate reinforcements and heat treatments on mechanical properties and damage evolution of Al-2618 metal matrix composites, Journal of Materials Science, 36, 2045(2001)
15	E. Pagounis, V. K. Lindroos, Influence of matrix structure on the abrasion wear resistance and toughness of a hot isostatic pressed white iron matrix composite, Metallurgical and Materials Transactions A, 27(12), 4183(1996)
16	F. Akhtar, S. J. Guo,Microstructure, mechanical and fretting wear properties of TiC-stainless steel composites, Materials Characterization, 59, 84(2008)
17	YANG Yufang, ZONG Yaping, WANG Gang, Manufacture of SiC particulate reinforced iron matrix composites by specimen current heating hot press sintering, Chinese Journal of Materials Research, 21(1), 67(2007)
17	(杨玉芳, 宗亚平, 王刚, 电流直加热动态热压烧结制备SiCp/Fe复合材料, 材料研究学报, 21(1), 67(2007))
18	A. Hung, K.M. Chen,Mechanism of Hypophosphite-Reduced Electroless Copper Plating, Journal of the Electrochemical Society, 136(1), 72(1989)

[1]	XING Dingqin, TU Jian, LUO Sen, ZHOU Zhiming. Effect of Different C Contents on Microstructure and Properties of VCoNi Medium-entropy Alloys[J]. 材料研究学报, 2023, 37(9): 685-696.
[2]	PAN Xinyuan, JIANG Jin, REN Yunfei, LIU Li, LI Jinghui, ZHANG Mingya. Microstructure and Property of Ti / Steel Composite Pipe Prepared by Hot Extrusion[J]. 材料研究学报, 2023, 37(9): 713-720.
[3]	LIU Ruifeng, XIAN Yunchang, ZHAO Rui, ZHOU Yinmei, WANG Wenxian. Microstructure and Properties of Titanium Alloy/Stainless Steel Composite Plate Prepared by Spark Plasma Sintering[J]. 材料研究学报, 2023, 37(8): 581-589.
[4]	JI Yuchen, LIU Shuhe, ZHANG Tianyu, ZHA Cheng. Research Progress of MXene Used in Lithium Sulfur Battery[J]. 材料研究学报, 2023, 37(7): 481-494.
[5]	WANG Wei, XIE Zelei, QU Yishen, CHANG Wenjuan, PENG Yiqing, JIN Jie, WANG Kuaishe. Tribological Properties of Graphene/SiO₂ Nanocomposite as Water-based Lubricant Additives[J]. 材料研究学报, 2023, 37(7): 543-553.
[6]	LEI Zhiguo, WEN Shengping, HUANG Hui, ZHANG Erqing, XIONG Xiangyuan, NIE Zuoren. Influence of Rolling Deformation on Microstructure and Mechanical Properties of Al-2Mg-0.8Cu(-Si) Alloy[J]. 材料研究学报, 2023, 37(6): 463-471.
[7]	ZHANG Tengxin, WANG Han, HAO Yabin, ZHANG Jiangang, SUN Xinyang, ZENG You. Damping Enhancement of Graphene/Polymer Composites Based on Interfacial Interactions of Hydrogen Bonds[J]. 材料研究学报, 2023, 37(6): 401-407.
[8]	SHAO Mengmeng, CHEN Zhaoke, XIONG Xiang, ZENG Yi, WANG Duo, WANG Xuhui. Effect of Si²⁺ Ion Beam Irradiation on Performance of C/C-ZrC-SiC Composites[J]. 材料研究学报, 2023, 37(6): 472-480.
[9]	DU Feifei, LI Chao, LI Xianliang, ZHOU Yaoyao, YAN Gengxu, LI Guojian, WANG Qiang. Preparation of TiAlTaN/TaO/WS Composite Coatings by Magnetron Sputtering and their Cutting Properties on Titanium Alloy[J]. 材料研究学报, 2023, 37(4): 301-307.
[10]	ZHANG Jinzhong, LIU Xiaoyun, YANG Jianmao, ZHOU Jianfeng, ZHA Liusheng. Preparation and Properties of Temperature-Responsive Janus Nanofibers[J]. 材料研究学报, 2023, 37(4): 248-256.
[11]	WANG Gang, DU Leilei, MIAO Ziqiang, QIAN Kaicheng, DU Xiangbowen, DENG Zeting, LI Renhong. Interfacial Properties of Polyamide 6-based Composites Reinforced with Polydopamine Modified Carbon Fiber[J]. 材料研究学报, 2023, 37(3): 203-210.
[12]	LIN Shifeng, XU Dongan, ZHUANG Yanxin, ZHANG Haifeng, ZHU Zhengwang. Preparation and Mechanical Properties of TiZr-based Bulk Metallic Glass/TC21 Titanium Alloy Dual-layered Composites[J]. 材料研究学报, 2023, 37(3): 193-202.
[13]	MIAO Qi, ZUO Xiaoqing, ZHOU Yun, WANG Yingwu, GUO Lu, WANG Tan, HUANG Bei. Pore Structure, Mechanical and Sound Absorption Performance for Composite Foam of 304 Stainless Steel Fiber/ZL104 Aluminum Alloy[J]. 材料研究学报, 2023, 37(3): 175-183.
[14]	ZHANG Kaiyin, WANG Qiuling, XIANG Jun. Microwave Absorption Properties of FeCo/SnO₂ Composite Nanofibers[J]. 材料研究学报, 2023, 37(2): 102-110.
[15]	ZHOU Cong, ZAN Yuning, WANG Dong, WANG Quanzhao, XIAO Bolv, MA Zongyi. High Temperature Properties and Strengthening Mechanism of (Al₁₁La₃+Al₂O₃)/Al Composite[J]. 材料研究学报, 2023, 37(2): 81-88.

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Shared

Discussed