Engineering Physics - 1 PDF

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This document is lecture notes for engineering physics, focusing on properties of materials, including elasticity and various definitions. It also describes concepts like stress, strain, and various types of stress.

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ENGINEERING PHYSICS – 1
Subject Code: 303192101
UNIT 1 (Properties of Materials)
Dr. Samrat Sarkar (Assistant Professor)
Applied Sciences and Humanities, PIET
 CHAPTER-1A
Elastic Properties of Materials
Introduction
 Elasticity
❖ We have used the concept of a rigid body in which the distance between any two particles is
always fixed.

❖ But in the real scenario, when external forces are applied, a body may get deformed.

❖ When the body is under deformation, internal forces are developed which try to regain the
original shape of the body. The extent, to which the shape of a body is restored when the its
deforming forces are removed, varies from material to material.

❖ The property to restore the natural shape is called Elasticity. If a body completely gains its
natural shape after the removal of the deforming forces, it is called a perfectly elastic body.

❖ If a body remains in the deformed state and does not even partially regain its original shape
after the removal of the deforming forces, it is called perfectly plastic body.

❖ Quite often the deforming forces are removed, the body partially regains its original shape.
Such bodies are partially elastic.
 Elasticity
REASON FOR ELASTICITY
❖ A solid body is composed of great many molecules or atoms arranged in a particular
fashion.
❖ Each molecule is acted upon by the forces (coulombic forces) due to the neighboring
molecules. The solid takes such a shape that each molecule finds itself in a position
of stable equilibrium.
❖ When the body is deformed the molecules are displaced from their original positions
of stable equilibrium.
❖ The intermolecular distance change and restoring forces start acting on the
molecules which drive them back to their original positions and the body takes its
natural shape.
 Some definitions
Elasticity: The inherent property of a body due to which the body tries
to restore its normal shape is known as elasticity.
 Some definitions

Deforming force: A force when applied to a body, changes the shape of the
body is called deforming force. The deformations are of three types, length,
volume and shape.
 Some definitions
Restoring Force:

When deforming force is applied to a
body, it tries to deform the body.
At the same time due to internal property
of material a force is produced in the
body which opposes the deformation.
When the deforming force is removed,
restoring force reduces to nullify the
deformation.
In static equilibrium restoring force is
equal to deforming force i.e. external
force.
 Some definitions
Elastic body:

If a body can completely regain its original shape after removable of the
deforming force, it is called a perfect elastic body.
 Some definitions
Plastic body: If a body remains in deformed state and does not even
partially regain its original shape after the removal of deforming shape, it
is called a plastic body.
Stress
 Stress
Stress:
For a rod, length is more with comparison to thickness (cross-sectional area). When
external force is applied to a rod, it causes increase in the length resulting stress is
called tensile stress.
If due to application of external forces, length of the rod decreases the resulting
stress is compressive stress.
Types of Stress:
(1) Longitudinal Stress (Tensile and Compressive)
(2) Volume Stress (Hydraulic Stress)
(3) Shearing Stress (Tangential Stress)
Strain
 Stress versus Pressure
Difference between Stress and Pressure

STRESSStress PRESSURE
Pressure

Stress can be defined as the internal
Pressure can be defined as the amount of
resistive force to the deformation per unit
Stress can be defined as the internal resistive
area.
Pressure
force canunit
applied per bearea.
defined as the amount of
force to the deformation per unit area. force applied per unit area.
Due to stress, the pressure will not be
Due to pressure, stress will be developed.
developed.
Due to stress, the pressure will not be Due to pressure, stress will be developed.
developed. Stress can be either a positive or a negative The pressure is always a positive force
force

Stress can be either
Stress a positive
is developed or a negative
internally Pressure is exerted externally
The pressure is always a positive force
force
Stress may be tensile, compressive and
Pressure is always compressive
shear
Stress is developed internally Pressure is exerted externally

Stress may be tensile, compressive and shear Pressure is always compressive
Elastic Moduli
Hooke’s Law
Model of Elastic Behaviour

Stress strain curve has
different regions and points.
These regions and points are:

1. Proportional limit
2. Elastic limit
3. Yield point
4. Ultimate stress point
5. Fracture or breaking point
 Model of Elastic Behaviour: Proportional Limit
Hooke’s law: Strain in a material will stay
constant over a range of strain rates.
Proportional limit: The stress within an
elastic limit is directly proportional to the
strain produced in the material.
The proportionality constant is Elastic
modulus.
Elasticity: Measure of stretchiness of a
material.
The elastic limit is the point on the graph
where the material gradually returns to
its original size.
Beyond this limit: Plastic deformation.
Model of Elastic Behaviour : Elastic limit (Yield point)
 Model of Elastic Behaviour : Yield Point
The Yield point: Material starts to deform plastically.

Beyond this limit: Permanent deformation develops in the
material, which can't be undone. There are two yield points:
upper yielding point, lower yielding point.

Tensile strength: The region at which a material fails is
known as its “tensile strength.” This strength is determined
by the amount of stress the material can withstand before it
breaks. The material can handle the maximum load at its
maximum strength point. Beyond this point, failure will occur.
The graph shows the stress points at which a material or
structure tends to break is the most critical, as it represents
the point of ultimate stress.

Fracture point: The fracture point is the point at which the
material breaks. The fracture or breaking of material takes
place at this point due to the force of the impact. The point at
which the graph breaks is called point E.
Some Terminologies
Some Terminologies
Some Terminologies
Some Terminologies
 CHAPTER-1B
Thermal Properties of Materials
 Modes of Heat Transfer

CONDUCTION OF HEAT
❖ Heat conduction is a process in which heat is transferred from the hotter
part to the colder part in a body without involving any actual movement of
the molecules of the body.
❖ Heat transfer takes place from one molecule to another molecule as a
result of the vibratory motion of the molecules.
❖ It generally takes place in solids. Substances can be classified as thermal
conductors and insulators. Substances that conduct heat easily are known
as conductors and those that do not conduct heat are known as insulators.
❖ Example: Frying vegetables in a pan.
 Modes of Heat Transfer
CONDUCTION
Conduction is the transfer of thermal energy through direct contact.
Occurs in solid materials.
 Modes of Heat Transfer

CONVECTION OF HEAT
❖ In this process, heat is transferred in liquids and gases from a region of
higher temperature to a region of lower temperature.
❖ Convection heat transfer occurs partly due to the actual movement of
molecules or due to the mass transfer.
❖ Example: Heating of milk in a pan, heating of atmosphere.
 Modes of Heat Transfer
CONVECTION
Convection is the process of heat transfer by the bulk movement
of molecules within fluids such as gases and liquids.
 Modes of Heat Transfer

RADIATION OF HEAT
❖ It is the process in which heat is transferred from one body to another
body without involving the molecules of the medium.
❖ Radiation heat transfer does not depend on the medium.
❖ Example: Earth receives heat from Sun by radiation. In a microwave, the
substances are heated directly without the need of any heating medium.
 Modes of Heat Transfer
RADIATION
Radiation is a process where heat waves (EM waves) are emitted that
may be absorbed, reflected, or transmitted through a colder body.
Modes of Heat Transfer
Electric Conductivity
Electric Conductivity
Electric Conductivity
Thermal Conductivity
Thermal Conductivity
Thermal Conductivity
Electrical versus Thermal Conductivity
Wiedemann-Franz law
 Thermoelectric Effect
Turning temperature differences directly into
electricity could be an efficient way of
harnessing heat that is wasted in cars and
power plants.
The simple interpretation of the thermoelectric
effect is the temperature difference or the
temperature gradient within the material can
induce electric current or electric voltage within it.
This process is reversible.
If there is potential difference between any two
points of material, the temperature gradient is
induced. Which means flowing current or
potential difference can produce temperature
difference or temperature gradient is material.
 Thermoelectric Effect
SEEBECK EFFECT- The Seebeck effect is
the build up of an electric potential across a
temperature gradient.
A thermocouple measures the difference in
potential across a hot and cold end for two
dissimilar materials.
This potential difference is proportional to the
temperature difference between the hot and
cold ends.
First discovered in 1794 by Italian scientist
Alessandro Volta, it is named after Thomas
Johann Seebeck, who in 1821 independently
rediscovered it.
Thermoelectric Effect
 Thermoelectric Effect
PELTIER EFFECT - When an electric current is passed through a circuit of a
thermocouple, heat is evolved at one junction and absorbed at the other junction. This is
known as the Peltier Effect.

The Peltier effect is the presence of heating or cooling at an electrified junction of
two different conductors and is named after French physicist Jean Charles Peltier, who
discovered it in 1834.

When a current is made to flow through a junction between two conductors, A and B,
heat may be generated or removed at the junction. The Peltier heat generated at the
junction per unit time is,

where πA and πB are the Peltier coefficients of conductors A and B, and I is the electric
current (from A to B). The total heat generated is not determined by the Peltier effect
alone; as it may also be influenced by Joule heating and thermal gradient effects.
 Thermoelectric Effect
THOMSON EFFECT - William Thomson discovered a 3rd thermoelectric effect which
provides a link between Seebeck effect and Peltier effect.

Thomson found that when a current is passed through an wire of single
homogeneous material along which a temperature gradient exists, heat must be
exchanged with the surrounding in order that the original temperature gradient may be
maintained along the wire.

Thomson effect may be understood by a simple picture. A conductor has free charge
carriers. Consider a section of such a conductor whose one end is hotter than the other
end.

Charge carriers at the hot end, being more energetic, will diffuse towards the
colder end. The charge separation sets up an electric field.

Diffusion of carriers would stop when the attractive force on the carriers due to this field
is strong enough to retard the motion of the carriers due to thermal effect.
Thermoelectric Effect
Reason of Thermoelectricity
Applications of Thermoelectricity
Applications of Thermoelectricity
Phonons
Phonons
Specific Heats of Solids
Specific Heats of Solids
Specific Heats of Solids
Quantum Theory
Specific Heats of Solids
Quantum Theory
Specific Heats of Solids
DEBYE MODEL EINSTEIN MODEL
Specific Heats of Solids
Statistical Distributions
Statistical Distributions
 Problems
1. An iron wire of length 1 m and radius 0.1 mm elongates by 0.32 mm when stretched
by a force of 49 N. Calculate the elastic constant of iron.

2. Show that the Poisson's ratio, σ = 0.5 for a cylinder whose volume remains unchanged
upon the application of a longitudinal stress.

3. A spring of force constant ‘k’ is cut into 4 equal parts perpendicular to the length. Find
the force constant of each equal part.

4. The bulk modulus of a spherical object is ‘B’. If it is subjected to a uniform pressure ‘p’
then show that the fractional decrease in radius is p/3B.

5. A wire of length L and cross-sectional area A is made of a material of Young’s modulus
Y. If the wire is stretched by an amount x, show that the work done is W = YAx2/2L.

6. Prove that the elastic potential energy stored in an elastic body per unit volume is
given by, u = 1/2 x Stress x Strain.
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