Preface
Page: i-ii (2)
Author: Virat Khanna, Prianka Sharma and Santosh Kumar
DOI: 10.2174/9789815223439124010001
Metal Matrix Composites: An Introduction and Relevance to Modern Sustainable Industry
Page: 1-17 (17)
Author: Virat Khanna*, Rakesh Kumar and Kamaljit Singh
DOI: 10.2174/9789815223439124010003
PDF Price: $15
Abstract
Metal matrix composites (MMCs) are a family of strong yet lightweight
materials that have many industrial uses, particularly in the automotive, aerospace, and
thermal management industries. By choosing the best combinations of matrix,
reinforcement, and manufacturing techniques, the structural and functional features of
MMCs may be adjusted to meet the requirements of diverse industrial applications. The
matrix, the interaction between them, and the reinforcement all affect how MMCs
behave. Yet, there is still a significant problem in developing a large-scale, costeffective MMC production method with the necessary geometrical and operational
flexibility. This chapter provides an overview of Metal Matrix Composites (MMCs),
their historical development, properties of MMCs, classification of MMCs, diverse
applications, and the relevance of MMCs to sustainable industries.
Structure-Property Correlations in Metal Matrix Composites
Page: 18-41 (24)
Author: Neeraj Kumar Sharma* and Abhimanyu Singh Rana
DOI: 10.2174/9789815223439124010004
PDF Price: $15
Abstract
Metal matrix composites (MMCs) having particulate or laminate structure
are extensively used in a wide range of applications including cutting tools, automotive
vehicles, aircraft, and consumer electronics. In a composite material, two or more
dissimilar materials are combined to form another material having superior properties.
The matrix is a continuous phase in a composite material and is usually more ductile
and less hard phase. In the matrix phase, aluminum, magnesium, titanium and copper
are some of the metals widely used matrix materials. Compared with unreinforced
metals, MMCs offer much better mechanical and thermal properties as well as the
opportunity to tailor these properties for a particular application. In order to fabricate
MMCs, various processing techniques have been evolved which can be categorized as
liquid state method: Stir Casting, Infiltration, Gas Pressure Infiltration, Squeeze
Casting Infiltration, Pressure Die Infiltration, solid state method: Diffusion bonding,
Sintering and vapor state method: Electrolytic co-deposition, Spray co-deposition and
Vapor co-deposition. The microstructure of MMCs such as orientation, distribution and
aspect ratio of reinforced phase can effectively influence the properties of composite
materials. The effective properties of MMCs can be predicted using the analytical or
numerical methods. Analytical methods such as: Turner Model, Kerner Model,
Schapery bonds, Hashin’s bond and Rule-of-Mixtures are used widely for effective
properties computation. However, analytical methods cannot take into account the
material microstructure, and therefore, the finite element method has been used
extensively to model the real microstructure of composites and to predict the
deformation response and effective properties of composites.
A Critical Review of Fabrication Techniques and Possible Interfacial Reactions of Silicon Carbide Reinforced Aluminium Metal Matrix Composites
Page: 42-90 (49)
Author: Jatinder Kumar*, Dilbag Singh and Nirmal S. Kalsi
DOI: 10.2174/9789815223439124010005
PDF Price: $15
Abstract
In this review article, the current status of and recent developments in
fabrication techniques for all types of Silicon Carbide reinforced Aluminium Metal
Matrix Composites (SiC-AMMCs) have been elaborately discussed. The comparative
studies on fabrication methods have also been reported in this article. Furthermore, the
possible interfacial reactions between aluminium and silicon carbide that have been
presented by researchers were also explored and their causes and remedies have been
discussed. The entire discussion in this review article reveals that liquid fabrication
processes (especially stir casting) are used effectively for mass production, intricate
shapes, a variety of products, nano-composites, etc. The solid-state processes are
performed below the melting temperature of matrices, resulting in the least possible
interfacial reactions leading to unwanted compounds’ formation. The literature on
interfacial reactions reveals that the Al4C3
compound is mostly formed as a result of the
reactions between aluminium and silicon carbide and exhibits a deleterious effect on
the composite properties.
Synthesis Approaches and Traits of Carbon Fibers-Reinforced Metal Matrix-Based Composites
Page: 91-115 (25)
Author: Himanshi, Rohit Jasrotia*, Suman, Ankit Verma, Sachin Kumar Godara, Abhishek Kandwal, Pawan Kumar, Jahangeer Ahmed and Susheel Kalia
DOI: 10.2174/9789815223439124010006
PDF Price: $15
Abstract
In this chapter, an overview of the advancement and research efforts that
have been undertaken on CFR-MMC (carbon-fiber reinforced metal matrix-based
composites) during the last several decades is presented. Carbon fiber is widely
implemented in the construction sector for rehabilitation and structural repair projects.
Although, studies show that carbon fiber-reinforced metal-matrix (CFR-MMC) has a
bright future, the use of carbon fibre as a reinforcement in metal matrix is still in its
development. The uses, and traits of carbon fiber are discussed in general terms in this
study. The various traits such as mechanical, and structural properties of the resultant
CFR-MMC, are significantly influenced by the structure and content of the carbon fibre
as well as its bonding to the MM (Metal matrix). The effect on the various traits of
MMCs by CFs (Carbon fibers) was investigated. In addition, a detailed study on the
various synthesis approaches for the preparation of CFR-MMC has been taken into
practice in this book chapter.
Fabrication and Interfacial Bonding of CNT-reinforced Metal Matrix Composites
Page: 116-146 (31)
Author: Prianka Sharma, Vidushi Karol, Sarabjeet Kaur and Manish Taunk*
DOI: 10.2174/9789815223439124010007
PDF Price: $15
Abstract
Recent advances in various engineering applications demand new materials
that have multi-functionality along with suitable structural properties. Metal matrix
composites are the class of materials that satisfy this purpose due to their lightweight,
increased strength, and other improved mechanical properties. These composite
materials can be prepared by various conventional techniques which aim reducing the
cost of production and meeting the demand of the industries efficiently. The properties
and functionality of these materials are greatly influenced by the type of reinforced
particulates and their composition in the metal matrix. Many reinforcement particles or
fibers can be used in MMC depending upon the applications. Commonly used
reinforced materials are graphene, polymers, carbon fibers, ceramic materials, etc.
Among the carbon family, carbon nanotubes (CNT) exhibit enhanced performance as
an ideal reinforcement material for MMCs. With outstanding intrinsic physical
properties, CNTs are considered a promising candidate for reinforcement. CNT owes
its properties due to its small diameter, high tensile strength, stiffness, high Young’s
modulus, and good chemical stability. They exhibit thermal stability even at high
temperatures and exhibit good electrical conductivity. They also show improved
fatigue resistance and plasticity and thus broaden the performance of the MMC. In this
chapter, various fabrication techniques along with blending and processing methods of
CNT-reinforced MMC have been discussed. The main methods have been explained
with their schematic representations. The advantages and limitations of these methods
have also been discussed. A strong interfacial bonding between the reinforced
particulate and the metal matrix affects the performance of the material. This chapter
also deals with a deep understanding of the various interfacial bonds that can exist
between CNT and the metal matrix
Biotribology: Recent advancements, Applications, Challenges and Future Directions
Page: 147-175 (29)
Author: Harpreet Singh* and Kirandeep Kaur
DOI: 10.2174/9789815223439124010008
PDF Price: $15
Abstract
Tribology deals with basic principles and understanding of three concepts:
friction, wear, and lubrication. Now, bio tribology is one of the most exhilarating fields
of tribological study. In this book chapter, the authors made efforts to review and
provide brief thoughts about the various sections of the biotribology such as
orthopedics, artificial implants, biomimetics, bio-lubricants, biomaterials, ocular
tribology, skin tribology, haptics, dental tribology, sports tribology. Apart from these,
biotribology deals with a few more exciting areas i.e., in personal care like skin creams,
cosmetics, etc., and oral processing studies such as mouthfeel and taste perception.
This comprehensive review comes to a close with four studies, i.e., bio-friction of the
biological systems, tribology of medical and surgical devices, biocompatibility issues
related to biomaterials, and critical aspects of bio-tribocorrosion. A critical review of
bio-friction studies for the various biological systems is presented, and significant
underlying tribological-lubrication mechanisms are also discussed.
The present emphasis and forthcoming advancements of the various medical and
surgical instruments in context with the fundamental tribology principles and
pertaining mechanisms for an efficient, versatile, and multi-functional bio-system will
be discussed in this book chapter. Furthermore, major challenges faced by R&D
officials and medical teams are discussed.
Biocompatibility and bio-tribo-corrosion of biomaterials are serious concerns in bio
tribology. In-depth discussions of current trends, implementations, and their guidelines
for the future are also included. In a nutshell, bio tribology studies can contribute
noteworthy scientific, social, engineering, and healthcare benefits; the openings and
possibilities are significant.
A Review on Reinforcement and Its Effect on Aluminium-Based Composites
Page: 176-199 (24)
Author: Anupam Thakur*, Virat Khanna and Qasim Murtaza
DOI: 10.2174/9789815223439124010009
PDF Price: $15
Abstract
In today’s world, there are different materials that are already used in certain
applications and have been performing well. As the need and the complications in
certain areas have been progressively discovered, there is a wide requirement for
materials’ research that has a combined effect of more than one property which is a
limitation of monolithic materials. To have such an effect, the fabrication of certain
materials having a well-tailored blend of properties as per the reinforcement is used to
form a composite. A review has been carried out for the various research works and the
effort is being made to summarize the effect of mono and hybrid reinforcements on the
materialistic properties as compared to the base material.
Hybrid Glass Fiber Reinforced Composites: Classification, Fabrication and Applications
Page: 200-223 (24)
Author: Rahul Mehra, Satish Kumar* and Santosh Kumar*
DOI: 10.2174/9789815223439124010010
PDF Price: $15
Abstract
The need to develop and use materials that are both much lighter and
stronger than current materials but are also more energy-efficient has been felt due to
the ongoing depletion of resources and the rising demand for component efficiency.
Composites are the best available suitable materials due to their excellent ultra-light
weight and outstanding strength characteristics. They have great energy absorption
capacity, high stiffness, high fracture toughness, and low thermal expansionin addition
to being highly strong in effect and light in weight. Today, composites are being used
in an increasing number of technical fields, from the automotive to aviation.
Corrosion and Wear Behaviour of Metal Matrix Composites
Page: 224-248 (25)
Author: Rakesh Kumar, Harsh Kumar, Santosh Kumar*, Mohit Kumar and Gaurav Luthra
DOI: 10.2174/9789815223439124010011
PDF Price: $15
Abstract
Metal matrix composite (MMC) has several attractive characteristics (low
coefficient of thermal expansion, lightweight, better abrasion, high strength-to-weight
ratio, superior stiffness, thermal stability, etc.), when compared with monolithic
materials. Due to these charming characteristics, MMC materials have received wide
scope in distinct industries (marine, aerospace, defence, mineral processing industry,
automotive, electronic, and recreation industries, etc.). But, owing to the requirement of
higher ductility and brittleness in the form of reinforcement and matrix, there is a need
to improve the properties of composite (MMC) that will fulfil the requirement of the
engineers. In addition, MMCs are typically more prone to corrosion and wear as
compared to their monolithic matrix alloys. Thus, the study of corrosion and wear
behaviour of distinct composites such as Al/SiC etc. are highly important for better
corrosion resistance for distinct applications. This chapter provides an overview of the
corrosion and wear behaviour of MMCs and applications.
An Experimental Investigation of Process Optimization of EDM for Newly Developed Aluminium Metal Matrix Composites
Page: 249-282 (34)
Author: Jatinder Kumar*, Gurpreet Singh and Santosh Kumar
DOI: 10.2174/9789815223439124010012
PDF Price: $15
Abstract
The aim of this investigation is to investigate the contribution of controllable
input parameters (viz. pulse on times, peak currents) on the performance of two newly
developed MMCs (Al-8.5%SiC-1.5%Mo and Al-7%SiC-3%Mo). Both the metal
matrix composites were fabricated using the stir-casting method. Thereafter, various
tests such as microhardness test, tensile test, and porosity analysis of the newly
developed composite were performed. To carry out the machining trials, an L18
orthogonal array (OA) was chosen. Optimization of the machining process was
performed according to Taguchi analysis followed by grey relational analysis (GRA).
The results showed that with increasing weight fraction of the molybdenum
particulates, microhardness and density of the composites increase with a small
reduction in the tensile strength. In addition, pulse on time is the most contributing
parameter among others to obtain optimal process performance. The optimum setting
of input variables suggested by GRA to obtain optimal responses is a molybdenum
composition of 3%, Pulse on time of 70 µs, and a peak current of 9A. Based on the
interaction plot, it is evident that process performance measures of EDM depend on
controllable input parameters.
Subject Index
Page: 283-288 (6)
Author: Virat Khanna, Prianka Sharma and Santosh Kumar
DOI: 10.2174/9789815223439124010013
Introduction
This book provides a comprehensive overview of metal matrix composite manufacturing, including fabrication methods, characterization techniques, and manufacturing applications. 10 chapters cover fundamental and applied topics on matrix metal composites. The book is a resource for all readers seeking to gain an in-depth understanding of metal matrix composites with its relevance to the modern industry. Key Features - Includes fully referenced contributions by experts in materials science - Provides an introduction to the subject, and a future prospective for a broad range of readers - Reviews current knowledge on fabrication techniques and structure property relationships of metal matrix composites - Includes dedicated chapters for reinforced composites (carbon fiber, carbon nanotubes, aluminium) - Includes guidance on material wear and tear and - Provides an investigation for process optimization for EDM for newly developed composites It is designed to be an essential resource for students and professionals in the field of materials science and engineering, as well as researchers and engineers working on metal matrix composite in manufacturing industries.