Enhancing Interfacial Bonding and Tensile Strength in CNT-Cu Composites by a Synergetic Method of Spraying Pyrolysis and Flake Powder Metallurgy

Carbon nanotube (CNT)-reinforced metal matrix composites (MMCs) face the problems of dispersion and interfacial wetting with regard to the matrix. A synergetic method of spray pyrolysis (SP) and flake powder metallurgy (FPM) is used in this paper to improve the dispersibility and interfacial bonding of CNTs in a Cu matrix. The results of the interface characterization show interface oxygen atoms (in the form of Cu2O) and a high density of dislocation areas, which is beneficial for interfacial bonding. The tensile results show that the tensile strength of the SP-CNT-Cu composites is much higher than that of the CNT-Cu composites when the mass fraction of the CNTs does not reach the critical value. This can be explained by the nanoparticles which are found on the surface of the CNTs during the SP process. These nanoparticles not only increase the tensile strength of the SP-CNT-Cu composites but also improve the dispersion of the CNTs in the Cu matrix. Thereby, uniform dispersion of CNTs, interfacial bonding between CNTs and the Cu matrix, and the enhancement of tensile strength are achieved simultaneously by the synergetic method.

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Uniform dispersion of multi-layer graphene reinforced pure titanium matrix composites via flake powder metallurgy

Materials Science and Engineering A ◽

10.1016/j.msea.2018.04.056 ◽

2018 ◽

Vol 725 ◽

pp. 541-548 ◽

Cited By ~ 26

Author(s):

X.N. Mu ◽

H.N. Cai ◽

H.M. Zhang ◽

Q.B. Fan ◽

F.C. Wang ◽

...

Keyword(s):

Powder Metallurgy ◽

Pure Titanium ◽

Matrix Composites ◽

Titanium Matrix ◽

Titanium Matrix Composites ◽

Layer Graphene ◽

Uniform Dispersion ◽

Flake Powder Metallurgy

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Effect of temperature on matrix multicracking evolution of C/SiC fiber-reinforced ceramic-matrix composites

High Temperature Materials and Processes ◽

10.1515/htmp-2020-0044 ◽

2020 ◽

Vol 39 (1) ◽

pp. 189-199

Author(s):

Longbiao Li

Keyword(s):

Strain Energy ◽

Ceramic Matrix Composites ◽

Critical Value ◽

Matrix Cracking ◽

Interface Debonding ◽

Matrix Composites ◽

Temperature Dependent ◽

Damage State ◽

The Matrix ◽

Sic Composites

AbstractIn this paper, the temperature-dependent matrix multicracking evolution of carbon-fiber-reinforced silicon carbide ceramic-matrix composites (C/SiC CMCs) is investigated. The temperature-dependent composite microstress field is obtained by combining the shear-lag model and temperature-dependent material properties and damage models. The critical matrix strain energy criterion assumes that the strain energy in the matrix has a critical value. With increasing applied stress, when the matrix strain energy is higher than the critical value, more matrix cracks and interface debonding occur to dissipate the additional energy. Based on the composite damage state, the temperature-dependent matrix strain energy and its critical value are obtained. The relationships among applied stress, matrix cracking state, interface damage state, and environmental temperature are established. The effects of interfacial properties, material properties, and environmental temperature on temperature-dependent matrix multiple fracture evolution of C/SiC composites are analyzed. The experimental evolution of matrix multiple fracture and fraction of the interface debonding of C/SiC composites at elevated temperatures are predicted. When the interface shear stress increases, the debonding resistance at the interface increases, leading to the decrease of the debonding fraction at the interface, and the stress transfer capacity between the fiber and the matrix increases, leading to the higher first matrix cracking stress, saturation matrix cracking stress, and saturation matrix cracking density.

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Study on the Dissolution and Precipitation Behavior of Self-Designed (NbTi)C Nanoparticles Addition in 1045 Steel

Metals ◽

10.3390/met11020184 ◽

2021 ◽

Vol 11 (2) ◽

pp. 184

Author(s):

Hongwei Zhu ◽

Haonan Li ◽

Furen Xiao ◽

Zhixiang Gao

Keyword(s):

Tensile Strength ◽

Electron Microscope ◽

Optical Microscope ◽

Cast Steels ◽

Uniform Dispersion ◽

The Matrix ◽

Thermo Calc Software ◽

Particle Strengthening ◽

1045 Steel ◽

Addition Amount

Self-designed (NbTi)C nanoparticles were obtained by mechanical alloying, predispersed in Fe powder, and then added to 1045 steel to obtain modified cast steels. The microstructure of cast steels was investigated by an optical microscope, scanning electron microscope, X-ray diffraction, and a transmission electron microscope. The results showed that (NbTi)C particles can be added to steels and occur in the following forms: original ellipsoidal morphology nanoparticles with uniform dispersion in the matrix, cuboidal nanoparticles in the grain, and microparticles in the grain boundary. Calculations by Thermo-Calc software and solubility formula show that cuboidal (NbTi)C nanoparticles were precipitated in the grain, while the (NbTi)C microparticles were formed by eutectic transformation. The results of the tensile strength of steels show that the strength of modified steels increased and then declined with the increase in the addition amount. When the addition amount was 0.16 wt.%, the modified steel obtained the maximum tensile strength of 759.0 MPa, which is an increase of 52% compared with to that with no addition. The hardness of the modified steel increased with the addition of (NbTi)C nanoparticles. The performance increase was mainly related to grain refinement and the particle strengthening of (NbTi)C nanoparticles, and the performance degradation was related to the increase in eutectic (NbTi)C.

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Enhanced interfacial bonding and mechanical properties in CNT/Al composites fabricated by flake powder metallurgy

Carbon ◽

10.1016/j.carbon.2018.01.037 ◽

2018 ◽

Vol 130 ◽

pp. 333-339 ◽

Cited By ~ 43

Author(s):

Genlian Fan ◽

Yue Jiang ◽

Zhanqiu Tan ◽

Qiang Guo ◽

Ding-bang Xiong ◽

...

Keyword(s):

Mechanical Properties ◽

Powder Metallurgy ◽

Interfacial Bonding ◽

Flake Powder Metallurgy

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Microstructure and Tensile Properties of Graphene-Oxide-Reinforced High-Temperature Titanium-Alloy-Matrix Composites

Materials ◽

10.3390/ma13153358 ◽

2020 ◽

Vol 13 (15) ◽

pp. 3358 ◽

Cited By ~ 1

Author(s):

Hang Chen ◽

Guangbao Mi ◽

Peijie Li ◽

Xu Huang ◽

Chunxiao Cao

Keyword(s):

Tensile Strength ◽

Titanium Alloy ◽

Graphene Oxide ◽

High Temperature ◽

Yield Strength ◽

Room Temperature ◽

Second Phase ◽

Matrix Composites ◽

Alloy Matrix ◽

The Matrix

In this study, graphene-oxide (GO)-reinforced Ti–Al–Sn–Zr–Mo–Nb–Si high-temperature titanium-alloy-matrix composites were fabricated by powder metallurgy. The mixed powders with well-dispersed GO sheets were obtained by temperature-controlled solution mixing, in which GO sheets adsorb on the surface of titanium alloy particles. Vacuum deoxygenating was applied to remove the oxygen-containing groups in GO, in order to reduce the introduction of oxygen. The compact composites with refined equiaxed and lamellar α phase structures were prepared by hot isostatic pressing (HIP). The results show that in-situ TiC layers form on the surface of GO and GO promotes the precipitation of hexagonal (TiZr)6Si3 particles. The composites exhibit significant improvement in strength and microhardness. The room-temperature tensile strength, yield strength and microhardness of the composite added with 0.3 wt% GO are 9%, 15% and 27% higher than the matrix titanium alloy without GO, respectively, and the tensile strength and yield strength at 600 °C are 3% and 21% higher than the matrix alloy. The quantitative analysis indicates that the main strengthening mechanisms are load transfer strengthening, grain refinement and (TiZr)6Si3 second phase strengthening, which accounted for 48%, 30% and 16% of the improvement of room-temperature yield strength, respectively.

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Mechanical and Tribological Properties of Ti3Al Reinforced Aluminium Matrix Composites

Advanced Composites Letters ◽

10.1177/096369350401300102 ◽

2004 ◽

Vol 13 (1) ◽

pp. 096369350401300 ◽

Cited By ~ 2

Author(s):

D. Busquets-Mataix ◽

N. Martvnez ◽

M.D. Salvador ◽

V. Amigσ

Keyword(s):

Mechanical Properties ◽

Tensile Strength ◽

Powder Metallurgy ◽

Aluminium Matrix ◽

Wear Behaviour ◽

Matrix Composites ◽

High Tensile Strength ◽

Tribological Behaviour ◽

Aluminium Matrix Composites ◽

Mechanical And Tribological Properties

Mechanical properties and tribological behaviour of AA6061 and AA7015 aluminium matrix composites reinforced with Ti3Al intermetallics have been studied. Processing of the composites consisted of a combination of powder metallurgy and extrusion techniques. High tensile strength was attained on both alloys, although composites did not improve these properties. Also ductility was impaired on composites, but values above 10% were obtained in every case. Regarding friction coefficient, all composites showed a lower value with respect to base alloys, being lower as the amount of reinforcement increased. Wear behaviour of composites was improved.

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Carbon nanotubes reinforced aluminum matrix composites with high elongation prepared by flake powder metallurgy

Diamond and Related Materials ◽

10.1016/j.diamond.2020.107907 ◽

2020 ◽

Vol 107 ◽

pp. 107907 ◽

Cited By ~ 1

Author(s):

N.Y. Li ◽

C. Yang ◽

C.J. Li ◽

H.D. Guan ◽

D. Fang ◽

...

Keyword(s):

Carbon Nanotubes ◽

Powder Metallurgy ◽

Aluminum Matrix ◽

Aluminum Matrix Composites ◽

Matrix Composites ◽

Flake Powder Metallurgy ◽

High Elongation

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Effect of the Matrix and Reinforcement Sizes on the Microstructure, the Physical and Mechanical Properties of Al-SiC Composites

Journal of Engineering Materials and Technology ◽

10.1115/1.4034959 ◽

2016 ◽

Vol 139 (1) ◽

Cited By ~ 3

Author(s):

M. A. Salem ◽

I. G. El-Batanony ◽

M. Ghanem ◽

Mohamed Ibrahim Abd ElAal

Keyword(s):

Mechanical Properties ◽

Powder Metallurgy ◽

Volume Fraction ◽

Physical And Mechanical Properties ◽

Particle Sizes ◽

Matrix Composites ◽

Volume Fractions ◽

The Matrix ◽

Sic Composites ◽

Sic Particle

Different Al-SiC metal matrix composites (MMCs) with a different matrix, reinforcement sizes, and volume fractions were fabricated using ball milling (BM) and powder metallurgy (PM) techniques. Al and Al-SiC composites with different volume fractions were milled for 120 h. Then, the Al and Al-SiC composites were pressed under 125 MPa and finally sintered at 450 °C. Moreover, microsize and combination between micro and nano sizes Al-SiC samples were prepared by the same way. The effect of the Al matrix, SiC reinforcement sizes and the SiC volume fraction on the microstructure evolution, physical and mechanical properties of the produced composites was investigated. The BM and powder metallurgy techniques followed by sintering produce fully dense Al-SiC composite samples with different matrix and reinforcement sizes. The SiC particle size was observed to have a higher effect on the thermal conductivity, electrical resistivity, and microhardness of the produced composites than that of the SiC volume fraction. The decreasing of the Al and SiC particle sizes and increasing of the SiC volume fraction deteriorate the physical properties. On the other hand, the microhardness was enhanced with the decreasing of the Al, SiC particle sizes and the increasing of the SiC volume fraction.

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