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ENGINEERING
MATERIALS AND
METALLURGY
UNIT-1
SYLLABI
SYLLABI
SYLLABI
Solid Solutions
Structure of Alloys
Phases in Alloys
1. Solid solutions
Variation in composition
Usually the crystal structure of the one of the solution is that of one of the
components
2. Compounds(Intermetallic Compounds)
Solid Solutions
A solid solution is a homogeneous mixture of 2 crystalline solids
with similar crystal lattices.
As in certain metal alloys, mixtures often consist of two or more
forms of atoms or molecules that share a crystal lattice.
The most abundant element or compound is referred to as a
solvent.
A tiny concentration of an element or compound is referred to as a
solute.
Solids have varying degrees of mutual solubility, similar to liquids,
based on their chemical characteristics and crystalline structure,
influencing how their atoms fit together in the mixed crystal lattice.
Solid Solutions
Combining the two solids after they have been melted into fluids
at high temperatures but then cooling the result to produce the
new solid or putting vapours of the precursors onto substrates
to form thin films are two steps to complete mixing.
Solid Solutions
The mixed lattice can be substitutional, with atoms from one
initial crystal changing those from the other, or interstitial, with
atoms occupying locations in the lattice that are ordinarily
vacant.
Alloy is a metal made up of a variety of components.
The majority of alloys are made up of a base metal and a few
additions of alloying elements.
Steel/cast iron (iron base alloys), bronze/brass (copper base alloys),
aluminium alloys, nickel-based alloys, magnesium base alloys, and
titanium alloys are typical examples of alloys.
Solid Solutions
Different technological procedures can be used to make alloys, such as
melting, sintering a powder mixture, high-temperature diffusion of an
alloying element into the base metal, plasma and vapour deposition of
various elements, electroplating, and so on.
The structure of an alloy might be single-phase or multi-phase.
A phase is a uniform section of an alloy with certain chemical
composition and structure, separated from the rest of the alloy by a
phase boundary.
An alloy phase can take the form of a valence compound (a substance
made up of two or more elements in which a fixed ratio determines the
composition) or a solid solution.
Solid Solutions
A solid solution refers to a state in which two or more elements
are entirely soluble in one another.
When two or more types of homogeneous atoms escape the
solid state, it is known as a solid solution.
Solid solutions are divided into two categories:
Interstitial solid solution
Substitutional solid solution
Solid Solutions
Interstitial solid solution:
The interstitial solid solution comprises solid solutions with an angstrom
number of less than one.
And this is generated when the interstitial solid solution is formed by the
space of lattice structure of a big solvent in which small atomic radii fit.
The solubility of this solid solution is limited.
The solid solution can be easily separated and has a high melting
temperature.
Example: carbon dissolves in iron.
Solid Solutions
Substitutional solid solution:
The solute atoms in the crystal lattice are substituted for the solvent atoms in
this form of solid solution.
The crystal structure does not change, although the addition of atoms causes
some deformation.
There is a variation in diameter between the solute and the solvent.
Ex: gold-silver alloy’s lattice structure remains unchanged.

Two Types :
1. Ordered – Al in CU – Al takes corner position and Cu takes Face Centered
Position
2. Random or Disordered – Most of the alloys
Hume Rothery Rules
The Hume-Rothery rules state that two elements will
likely form a substitutional solid solution when these
four conditions are met:
The atomic size of the solute atoms is within 15% of the
atomic size of the solvent atoms.
The two elements have similar crystal structures.
The two elements have similar electronegativities.
The two elements have similar valences.
Phase Diagram
Phase
Chemically homogeneous
Physically distinct
Mechanically separable
Phase Diagram
Relation of number of components
Number of phases
Degrees of freedom
Components
The composition in a material
Ex(1) : H20
Hydrogen and Oxygen are the 2 components
Where as the phase is 1(Liquid Phase)
Ex (2) : Water + Ice Bar
Hydrogen and Oxygen are the 2 components
Where as the phase is 2(Liquid Phase + Solid Phase)
Ex (3) : Mild Steel
Fe & C
In the room temperature – α,Fe3C
Phase Diagram – Cu-Ni
Reactions
What is Steel?

Steel is an alloy of Iron (the concept of alloy is explained
below) and the principal or main alloying element is Carbon.
Hence,
The main or base element in steel is: Iron
Main (principal) alloying element in steel is: Carbon
Other alloying elements in steel are:
Manganese, Silicon, Nickel, Chromium, Molybdenum, Vanadium,
Titanium, Niobium, Aluminum, etc
Types Of Steel
Carbon Steel
Carbon steel is the most utilized steel in industries and accounts
for over 90% of the total steel production.
Based on the carbon content, Carbon steels are further
classified into three groups.
Low Carbon Steel/Mild Steel
Medium Carbon Steel
High Carbon steel
Carbon Steel
Designation system - Carbon Steel
American Iron and Steel Institute (AISI) together with Society of Automotive
Engineers (SAE) have established four-digit (with additional letter prefixes)
designation system:
SAE 1XXX
First digit 1 indicates carbon steel (2-9 are used for alloy steels);
Second digit indicates modification of the steel.
0 - Plain carbon, non-modified
1 - Resulfurized
2 - Resulfurized and rephosphorized
5 - Non-resulfurized, Mn over 1.0%
Last two digits indicate carbon concentration in 0.01%.
Example: SAE 1030 means non modified carbon steel, containing
0.30% of carbon.
Carbon Steel
A letter prefix before the four-digit number indicates
the steel making technology:
A - Alloy, basic open hearth
B - Carbon, acid Bessemer
C - Carbon, basic open hearth
D - Carbon, acid open hearth
E - Electric furnace
Example: AISI B1020 means non modified carbon steel,
produced in acid Bessemer and containing 0.20% of
carbon
Stainless Steel

Stainless steel is an alloy steel that contains 10.5% Chromium
(Minimum).
Stainless steel exhibits corrosion resistance properties, due to the
formation of a very thin layer of Cr2O3 on its surface.
This layer is also known as the passive layer.
Increasing the amount of Chromium will further increase the
material’s corrosion resistance.
In addition to Chromium, Nickel, and Molybdenum are also added to
impart desired (or improved) properties.
Stainless steel also contains varying amounts of Carbon, Silicon,
and Manganese.
Stainless Steel
Stainless steels are further classified as;
1. Ferritic Stainless Steel
2. Martensitic Stainless Steel
3. Austenitic Stainless Steel
4. Duplex Stainless Steel
5. Precipitation-Hardening (PH) Stainless Steel
Stainless Steel
Ferritic Stainless Steel:
Ferritic steels consist of Iron-Chromium alloys with body-centered cubic
crystal structures (BCC). These are generally magnetic and cannot be
hardened by heat treatment but can be strengthened by cold working.
Austenitic Stainless Steel:
Austenitic steels are the most corrosion-resistant. It is non-magnetic
and non-heat-treatable. Generally, austenitic steels are highly weldable.
Martensitic Stainless Steel:
Martensitic stainless steels are extremely strong and tough but not as
corrosion-resistant as the other two classes. These steels are highly
machinable, magnetic, and heat-treatable.
Stainless Steel
Duplex Stainless Steels:
Duplex stainless steel consists of a two-phase microstructure
consisting of grains of ferritic and austenitic stainless steel (i.e Ferrite +
Austenite). Duplex steels are about twice as strong as austenitic or
ferritic stainless steels.
Precipitation-Hardening (PH) Stainless Steels:
Precipitation-Hardening (PH) Stainless Steels possess Ultra high
strength due to precipitation hardening.
Stainless Steel
AISI has established three-digit system for the stainless
steels:
2XX series – chromium-nickel-manganese austenitic
stainless steels;
3XX series –chromium-nickel austenitic stainless steels;
4XXseries–chromium martensitic stainless
steels or ferritic stainless steels;

5XX series – low chromium martensitic stainless steels;
Alloy Steel

In alloy steel, varying proportions of alloying elements are used,
to achieve desired (improved) properties such as weldability,
ductility, machinability, strength, hardenability, corrosion
resistance, etc.
Some of the most used alloying elements and their effects are
as follows;
Manganese – Increases strength and hardness, decreases ductility
and weldability
Silicon – Used as deoxidizers used in the steel-making process
Alloy Steel
Phosphorus – Increases strength and hardness and decreases
ductility and notch impact toughness of steel.
Sulphur –Decreases ductility, notch impact toughness, and weldability.
Found in the form of sulfide inclusions.
Copper – improved corrosion resistance
Nickel – Increases hardenability and Impact strength of steels.
Molybdenum – Increases hardenability and enhances the creep
resistance of low-alloy steels
Alloy Steel
Low alloy steels (alloying elements ⇐ 8%);
High alloy steels (alloying elements > 8%).

First digit indicates the class of the alloy steel:
2- Nickel steels;
3- Nickel-chromium steels;
4- Molybdenum steels;
5- Chromium steels;
6- Chromium-vanadium steels;
7- Tungsten-chromium steels;
9- Silicon-manganese steels.
Second digit indicates concentration of the major element in percents (1 means 1%).
Last two digits indicate carbon concentration in 0,01%.

Example: SAE 5130 means alloy chromium steel, containing 1% of chromium and 0.30% of carbon.
Tool Steel or Die Steel

Tool steels have high carbon content (0.5% to 1.5%).
Higher carbon content provides higher hardness and strength.
These steels are mostly used to make tools and dies.
Tool steel contains various amounts of tungsten, cobalt,
molybdenum, and vanadium to increase the heat and wear
resistance, and durability of the metal.
This makes tool steels very ideal for use as cutting and drilling
tools.
Tool Steel or Die Steel
Designation system of one-letter in combination with a number is accepted
for tool steels.
The letter means:
W - Water hardened plain carbon tool steels;
O - Oil hardening cold work alloy steels;
A - Air hardening cold work alloy steels;
D -Diffused hardening cold work alloy steels;
S – Shock resistant low carbon tool steels;
T – High speed tungsten tool steels;
M - High speed molybdenum tool steels;
H – Hot work tool steels;
P – Plastic mold tool steels.
Classification of cast irons

White cast irons - hard and brittle wear resistant cast irons
consisting of pearlite and cementite.
Grey cast irons - cast irons at slow cooling and consisting
of ferrite and dispersed graphite flakes.
Malleable cast irons - cast irons, produced by heat
treatment of white cast irons and consisting of ferrite and
particles of free graphite.
Nodular (ductile) cast irons - grey cast iron in
which Graphite particles are modified by magnesium added
to the melt before casting. Nodular cast iron consists of
spheroid nodular graphite particles in ferrite or pearlite
matrix.
Microstructure - CI
Applications

Steel Cast Iron
Rail car wheels, frames, and bolsters Cast iron frying pans and other cookware
Mining machinery, construction equipment, and heavy Automotive engine blocks, brake disks, and numerous
trucks other parts
Heavy duty pumps, valves, and fittings Residential fence gates, decorative light posts, fireplace
Turbochargers, engine blocks, and other automotive elements, and other furnishings
parts Valves, fittings, and manhole covers in water and sewer
Turbines and other components in power station applications
assemblies Chains, gears, shafts, linkages, and more
MCQ

Q O
Which of the following is a) Metals
a basic classification of b) Non-Metals
Engineering Materials? c) Both Metals & Non-
Metals
d) None of the mentioned
MCQ

Q O
Which of the following is a) Mechanical properties
not a property of b) Chemical properties
engineering materials? c) Polymorphism
d) Electrical properties
MCQ

Q O
Which of the following is a) Asbestos
a type of Engineering b) Ferrous Metals
Materials and is a Metal? c) Non-Ferrous Metals
d) Both b & c
MCQ

Q O
Which of the following a) Softness
attributes explain why b) Hardness
pure metals are not c) Brittleness
frequently used in d) Luster
engineering
applications?
MCQ

Q O
Which of the following a) Grain size
factors don’t affect the b) Shape of material
mechanical properties of c) Content of alloys
a material under applied d) Imperfection and
loads? defects
MCQ

Q O
Which of these is not a a) Improves ductility
function of alloy steels? b) Improves
machinability
c) Increases strength
d) Reduces cost
MCQ

Q O
Which of the following is a) Vanadium
the primary element b) Indium
used for making c) Chromium
stainless steel alloy? d) Zirconium
MCQ

Q O
Which of the following a) Chromium carbide
carbides are used for b) Silicon carbide
cutting tools? c) Tungsten carbide
d) Vanadium carbide
MCQ

Q O
What is the result of full a) Cementite
annealing of b) Coarse pearlite
hypoeutectoid steels? c) Silicon
d) Bainite
MCQ

Q O
White iron structure A) Pearlite
consists of B) Cementite
C) Ferrite
D) Pearlite and
Cementite
MCQ

Q O
The reaction in which a 1. Eutectoid Reaction
liquid phase transform 2. Peritectic Reaction
into two different solid
phases is called 3. Peritectoid Reaction
4. Eutectic Reaction
MCQ

Q O
Which of the following 1. Ferrite
phase of steel is not 2. Cementite
present in the Fe-Fe3C
Diagram? 3. Austenite
4. Martensite
MCQ
Q
O
The eutectic reaction of 1. 527’C
Iron-Carbon occurs at 2. 1493’C
3. 1147’C
4. 723’C
MCQ
Q
O
The eutectic point in the a) 0.022
iron-iron carbide phase b) 0.77
diagram occurs at c) 2.11
__________ weight % d) 4.30
composition of carbon.
MCQ

Q O
At what temperature a) 1674 F
does δ ferrite melt? b) 1990 F
c) 2541 F
d) 2800 F
MCQ

Q O
What is the solubility of a) 0.1%
α ferrite at 0oC? b) 0.02%
c) 0.005%
d) 0.0004%
MCQ

Q O
At what temperature a) 1778oC
does peritectic reaction b) 1495oC
occur? c) 1148oC
d) 723oC