Dielectrics and Ferroelectric Materials PDF

Summary

This document provides an overview of dielectrics and ferroelectric materials, covering topics like dielectric constant, dielectric strength, and electric displacement and their applications. It appears to be lecture notes or study material, rather than an exam paper.

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Dielectrics and Ferroelectric Materials

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Course Syllabus

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 Dielectric Material
A dielectric material is one that is electrically insulating (nonmetallic) and exhibits or may be
made to exhibit an electric dipole structure (molecular or atomic level).

In principle all insulators are dielectric, although the capacity to support charge varies greatly between
different insulators

Dielectric materials are used in many applications, from simple electrical
insulation to sensors and circuit components.

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Electric Dipole

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 Dielectric Constant

Dielectric Constant: Also known as relative permittivity
ε
ε𝑟 =
ε0

ε = Permittivity of medium
ε0 Permittivity of vacuum (8.854⨯10−12 𝐹/𝑚)

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 Dielectric Strength

The dielectric strength, sometimes called the breakdown strength, represents
the magnitude of an electric field necessary to produce breakdown.

Sometimes localized melting, burning, or vaporization produces
irreversible degradation and perhaps even failure of the material

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 Electric Displacement
Charge per unit area that would be displaced across a
layer of conductor placed across an electric field.
Also known as electric flux density or Surface charge
density.

Electric displacement is used in the dielectric material to
find the response of the materials on the application of an
electric field E.

The SI unit Coulomb per meter square (C m-2).

D = 𝜺𝟎 𝑬 + 𝑷
The surface charge density D, or quantity of charge
per unit area of capacitor plate (C/m2), is
ϵ0: Vacuum permittivity proportional to the electric field
P: Polarization density
E: Electric field
D: Electric displacement field

The electric displacement field D represents how an electric field E influences the organization of electric
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charges in a given medium, including charge migration and electric dipole reorientation.
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Capacitor

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 Capacitor

Ceramic capacitors. (a) Section showing construction. (b) Steps in manufacture:
(1) after firing ceramic disk; (2) after applying silver electrodes; (3) after soldering
leads; (4) after applying dipped phenolic coating.
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Representative formulations for some ceramic dielectric materials for capacitors

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Parallel Plate Capacitor in the presence of dielectric

Plate A

Plate B

D = E𝜺𝟎 + 𝑷
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Dipole orientations for change in orientation of electric field.

In reality, a dipole moment is a vector that is directed from the
negative to the positive charge

In the presence of an electric field E, which is also a vector
quantity, a force (or torque) will come to bear on
an electric dipole to orient it with the applied field.

The process of dipole alignment is termed polarization.

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Polarization Mechanism

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 Polarization
Polarization direction -ve to +ve

Polarization is dipole moment per unit volume
Polarization is the alignment of permanent or induced atomic or
molecular dipole moments with an externally applied electric field.
Electronic polarization

Results from a displacement of the center of the negatively charged electron cloud
relative to the positive nucleus of an atom by the electric field
This polarization type is found in all dielectric materials and, of course, exists
only while an electric field is present.

Ionic Polarization

Ionic polarization occurs only in materials that are ionic. An applied field acts to
displace cations in one direction and anions in the opposite direction, which gives
rise to a net dipole moment.

Orientation or dipolar Polarization

It is found only in substances that possess permanent dipole moments. Polarization
results from a rotation of the permanent moments into the direction of the applied
field,
This alignment tendency is counteracted by the thermal vibrations of the atoms,
such that polarization decreases with increasing temperature. 16
HCl molecule

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Interfacial Polarization or Space Charge Polarization

It occurs when there is an accumulation of charge at an interface between two materials or between two
regions within a material because of an external field. This can occur when there is a compound dielectric,
or when there are two electrodes connected to a dielectric material.

This type of electric polarization is different from orientational and ionic polarization because instead of
affecting bound positive and negative charges i.e. ionic and covalent bonded structures, interfacial
polarization also affects free charges as well.

As a result interfacial polarization is usually observed in amorphous or polycrystalline solids.
Free Charges

The electric field will cause a charge imbalance
because of the dielectric material's insulating
properties.

However, the mobile charges in the dielectric will
migrate over maintain charge neutrality. This then
causes interfacial polarization

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Dielectric Constant

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Relaxation Time
A dielectric becomes polarised in an electric field. Now imagine switching the
direction of the field. The direction of the polarisation will also switch in order to
align with the new field. This cannot occur instantaneously: some time is needed
for the movement of charges or rotation of dipoles.
If the field is switched, there is a characteristic time that the orientational
polarisation (or average dipole orientation) takes to adjust, called the relaxation
time.

Typical relaxation times are ~10-11 s.

Therefore, if the electric field switches direction at a frequency higher than
~1011 Hz, the dipole orientation cannot ‘keep up’ with the alternating field, the
polarisation direction is unable to remain aligned with the field, and this
polarisation mechanism ceases to contribute to the polarisation of the dielectric.
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 Dielectrics Losses

For each polarization type, some minimum reorientation time exists, which depends on the ease
with which the particular dipoles are capable of realignment. (A)
A relaxation frequency
is taken as the reciprocal of this minimum reorientation time

A dipole cannot keep shifting orientation direction when the frequency of the
applied electric field exceeds its relaxation frequency and, therefore, will not make
a contribution to the dielectric constant.

The absorption of electrical energy by a dielectric material that is subjected to
an alternating electric field is termed dielectric loss.
A.C field
A low dielectric loss is desired at the frequency of utilization.
(B)
180o Oscillation of dipoles
+

- Animation
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 Dielectric Loss
Dielectric loss is the dissipation of energy through the movement of charges in an alternating electromagnetic field as
polarisation switches direction.

Dielectric loss is especially high around the relaxation or resonance frequencies of the polarisation mechanisms as the
polarisation lags behind the applied field, causing an interaction between the field and the dielectric’s polarisation that
results in heating.

Dielectric loss tends to be higher in materials with higher dielectric constants. This is the downside of using these
materials in practical applications.

Dielectric loss is utilized to heat food in a microwave oven

Microwave Heating
The frequency of the microwaves used is close to the relaxation
frequency of the orientational polarisation mechanism in water,
meaning that any water present absorbs a lot of energy that is then
dissipated as heat.

The exact frequency used is slightly away from the frequency at which
maximum dielectric loss occurs in water to ensure that the microwaves
are not all absorbed by the first layer of water they encounter,
therefore allowing more even heating of the food. 23
 Dielectric Loss Factor
If the voltage used to maintain the charge on a capacitor is sinusoidal, as is
generated by an alternating current, the current leads the voltage by 90
degrees when a loss-free dielectric is between the plates of a capacitor.

However, when a real dielectric is used in the capacitor, the current leads
the voltage by (90° - δ), where the angle δ is called the dielectric loss
angle.

The product of dielectric cosntant(κ) tan δ is designated the loss factor
and is a measure of the electric energy lost (as heat energy) by a capacitor
in an ac circuit.
Note: In circuits with primarily capacitive loads, current leads
the voltage. This is true because current must first flow to the
two plates of the capacitor, where charge is stored. Only after
charge accumulates at the plates of a capacitor is a voltage
difference established.
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 Dielectric Breakdown
At high electric fields, a material that is normally an electrical insulator may begin to conduct
electricity – i.e. it ceases to act as a dielectric. This phenomenon is known as dielectric
breakdown.

If the electric field across an insulator is too high, the insulator will start to conduct a current. This
phenomenon is known as dielectric breakdown.

The mechanism for the breakdown is that some free carriers (e.g., caused by impurities) are
accelerated in the field, so much that they can ionize other atoms and generate more free
carriers. Then, the breakdown proceeds like an avalanche.

The breakdown can be facilitated by operating the material close to a resonance frequency where
much energy is dissipated, the material is heated, and the probability of having free carriers is
increased.

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Linear and Non-Linear
Dielectrics

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Ferroelectric Materials

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 FERROELECTRICITY

The group of dielectric materials called ferroelectrics exhibit spontaneous
polarization—that is, polarization in the absence of an electric field. They are the
dielectric analogue of ferromagnetic materials, which may display permanent
magnetic behavior. BaTiO3

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 4
3

Non-centrosymmetric structure and origin of
piezoelectricity (a) centrosymmetric structure and
(b) non-centrosymmetric structure

Perovskite structure of oxides ABO3
ferroelectric
phase with upward and downward polarization.
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 + -
+
- +

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(a) Schematic illustration of electric dipoles within a piezoelectric material.

(b)Compressive stresses on material cause a voltage difference to develop due to
change in electric dipoles.

(c) Applied voltage across ends of a sample causes a
dimensional change and changes the electric dipole moment.

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 4
7

Fig. 5 Dipole configuration in ferroelectric mateirals.
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 Review of Voltage or Charge Measurement in Piezo and Pyroelectrics

Electroding (Silver paste)
+ - = Bounded Charge
+ - = Free Charge
- - - -
+ + + +
Bounded Charge density changes due to the change in the
Polarisation state of the sample which is further dependent on
the external stimulus such as mechanical force or change in
V temperature

Insulating Material
- - - - (Dielectric)
+ + + +

+

-
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Depolarisation
1. Thermal depoling
If the material is exposed to excessive heat, such that its temperature approaches its Curie temperature, the dipole
moments regain their unaligned state. At the Curie temperature, a ferroelectric becomes entirely unaligned. In order
to prevent this occurring, it is sensible to use piezoelectrics well below their Curie temperature.

2. Electrical depoling
A strong electric field, when applied in the reverse direction to the already poled material, will lead to depoling. If an
alternating field is used to produce ultrasound waves (see later) the field will depolarise the piezoelectric during the
periods in which it is opposing the polarisation.

3. Mechanical depoling
If the stress placed on a piezoelectric is too high, it is possible to immediately depolarise the piezoelectric as the atom
positions are altered. This completely ruins its properties.

Source: https://www.doitpoms.ac.uk/tlplib/piezoelectrics/depolarisation.php
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A = Saturation Polarization

B= Remnant Polarization

C= Coercive Field

Credits: Dr. Sumeet K Sharma

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Sawyer Tower Circuit for P-E loop measurement

Polarization = Dipole moment / Volume

= C.m /m3

= C/m2
= Charge/ Area

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Explanation:

In this experiment, the voltage is cycled by the signal generator. Its direction is reversed at high frequency, and the
voltage across the reference capacitor is measured.

The charge on the capacitor must be the same as the charge over the ferroelectric capacitor, as they are in series.
This means the charge on the ferroelectric can be found by:

Q=C×V
where C is the capacitance of the reference capacitor, and V is the voltage measured over this capacitor.

We can therefore represent the polarisation of a material in an oscillating electric field, by plotting the voltage
applied to the material on the x-axis of the oscilloscope, and the surface charge on the y-axis.

This can be done because the capacitance of the reference capacitor is much higher than the capacitance of the
ferroelectric, so most of the voltage lies over the ferroelectric. It is only possible to measure P by cycling the
polarisation through cycling the voltage across the ferroelectric. We cannot measure absolute values
instantaneously , but can deduce absolute values from the changes measured when cycling the polarisation.

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Curie Temperature:
The temperature at which
the Ferroelectric
properties or the capability
to get spontaneous

polarization is lost.
Temperature dependence of the Hysteresis loop
We have only observed it at one particular temperature, one at which the material is ferroelectric. What happens if the
temperature is raised?

The hysteresis loop changes with temperature, becoming sharper and thinner, and eventually disappearing

As you can see, the polarisation increases at 90°C, as a result of a phase transition. Between this temperature and
room temperature, the polarisation increases steadily, as a direct relation with temperature, such that:
ΔP = p ΔT
where p = pyroelectric coefficient (C m-2 T-1).

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 Brief History of Pyroelectricity

Pyroelectricity as a phenomenon has been known for 24 centuries—the Greek philosopher Theophrastus probably
wrote the earliest known account. He described a stone, called lyngourion in Greek or lyncurium in Latin, that had the
property of attracting straws and bits of wood.

Those attractions were no doubt the effects of electrostatic charges produced by temperature changes most probably in
the mineral tourmaline.

Theophrastus and other writers of the two millennia that followed were far more interested in the origin of the stone
and its physical explanations. Theophrastus proposed that lyngourion was formed from the urine of a wild animal.

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Introduction
Pyroelectrics are the bridge between ferroelectrics and piezoelectrics.

They possess a spontaneous polarisation which is not necessarily switchable by an electric field.

If their polarisation is switchable, i.e. they are ferroelectric, then they are mainly used in situations in which
ferroelectric properties are required.

However, if they are not ferroelectric, then their properties as pyroelectrics are more useful.

Whether a given sample possesses a net dipole moment depends on domain configurations, which in turn
depend on sample history. This polarisation will change when a stress is applied to the material, as pyroelectrics
are a sub-set of piezoelectrics.

But it will not reverse under the application of an electric field because it will breakdown first, i.e. the coercive
field exceeds the breakdown field.

This is only true for a pyroelectric material which is not ferroelectric, whereas if it is ferroelectric, the coercive
field is smaller than the breakdown field. In other words, ferroelectrics are a subset of pyroelectrics.

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 Pyroelectricity

Pyro =fire,” “heat,” “high temperature

Pyroelectricity is the property presented by certain materials that exhibit an
electric polarization ∆P when a temperature variation ∆T is applied
uniformly:

∆P = γ∆T

where γ is the pyroelectric coefficient at constant stress.

Pyroelectric crystals actually have a spontaneous polarization,

but the pyroelectric effect can only be observed during
a temperature change (ΔT).

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 If a spontaneous polarization is already present, a change of temperature alters it.

The change in temperature modifies the positions of the atoms slightly within the crystal structure, such that the
polarization of the material changes.

This polarization change gives rise to an electric polarization across the crystal.

If the temperature stays constant at its new value, the pyroelectric polarization gradually disappears due to leakage current
(the leakage can be due to electrons moving through the crystal, ions moving through the air, current leaking through a
voltmeter attached across the crystal, and so on)

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Types of Ferroelectric Materials and Their
Applications

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 Types of Ferroelectric Materials
Perovskite-Type Structures

Perovskite is a family name of a group of materials having the mineral name of calcium titanate (CaTiO3) exhibiting a
structure of the type ABO3. Many piezoelectrics including FE ceramics such as

Barium titanate (BaTiO3)
Strontium titanate (STO) (SrTiO3)
Barium strontium titanate (BST)
Lead titanate (PbTiO3), Lead Zirconate Titanate (PZT)
Lead Lanthanum Zirconate Titanate (PLZT)
Lead Magnesium Niobate (PMN)
Potassium niobate (KN) (KNbO3),
Potassium sodium niobate (KxNal-xNbO3),
and Potassium tantalate niobate (KTaxNbl-xO3)
have a perovskite-type structure.

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Barium titanate (BaTiO3)

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 Strontium Titanate (SrTiO3)

Barium Strontium Titanate (BST)

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Lead Titanate (PbTiO3) Lead Zirconate Titanate (PZT)

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 Polymers based Piezoelectrics
Organic Polymers

Molecular structure of ferroelectric polymer
(a) Polyvinylidene fluoride or Polyvinylidene difluoride (PVDF) and (b)
Polyvinylidene fluoride-trifluoroethylene P(VDF-TrFE)

Ceramic Polymer Composites
Ceramic polymer materials are inorganic–organic composites consisting of ceramic fillers and a matrix of organic polymers. The formation
of ceramic polymer is based on thermal curing of functionalized resins being able to form ceramic-like structures as a result of heat
treatment above 200 deg.C.

Processed by a broad variety of plastic-forming techniques such as high-pressure injection molding or extrusion.

Ceramic Polymer composites are characterized by high thermal stability (possible service temperatures above
600 deg. C), low shrinkage, high stability of shape, and high dimensional accuracy.

Relevant usage properties (e.g., electrical conductivity, thermal conductivity) and processing parameters can be adjusted by the choice of
appropriate functional fillers, binder systems, and plasticizing additives.

The application of ceramic polymer materials could pay off if a cost-efficient, easy processing of the material including plastic-forming
techniques in order to realize complex shaped parts is required and the thermal stability of standard materials such as plastics does not
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suffice.
 Phase Diagram

MPB: Coexistence of Rhombohedral and Tetragonal Phases

Good Piezoelectric properties due to the coexistence of
two phases.

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Piezoelectric Constants one needs to know

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Charge Constant

Voltage Constant

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Piezoelectric Charge Constant

𝑃𝑜𝑙𝑎𝑟𝑖𝑧𝑎𝑡𝑖𝑜𝑛
d=
𝑀𝑒𝑐ℎ𝑎𝑛𝑖𝑐𝑎𝑙 𝑆𝑡𝑟𝑒𝑠𝑠

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Source: https://www.americanpiezo.com/
Piezoelectric Voltage Constant

𝐸𝑙𝑒𝑐𝑡𝑟𝑖𝑐 𝐹𝑖𝑒𝑙𝑑
g=
𝑀𝑒𝑐ℎ𝑎𝑛𝑐𝑖𝑎𝑙 𝑆𝑡𝑟𝑒𝑠𝑠

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Permittivity Constant

𝐷𝑖𝑒𝑙𝑒𝑐𝑡𝑟𝑖𝑐 𝐷𝑖𝑠𝑝𝑙𝑎𝑐𝑒𝑚𝑒𝑛𝑡
ε=
𝐸𝑙𝑒𝑐𝑡𝑟𝑖𝑐 𝐹𝑖𝑒𝑙𝑑

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Elastic and Compliance Inverse of Modulus of Elasticity

𝑀𝑒𝑐ℎ𝑎𝑛𝑐𝑖𝑎𝑙 𝑆𝑡𝑟𝑎𝑖𝑛
s=
𝑀𝑒𝑐ℎ𝑎𝑛𝑐𝑖𝑎𝑙 𝑆𝑡𝑟𝑒𝑠𝑠

Young’s Modulus

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Electromechanical Coupling Factor

𝐸𝑙𝑒𝑐𝑡𝑟𝑖𝑐𝑎𝑙 𝐸𝑛𝑒𝑟𝑔𝑦 𝑀𝑒𝑐𝑎ℎ𝑛𝑖𝑐𝑎𝑙 𝐸𝑛𝑒𝑟𝑔𝑦
k= OR
𝐸𝑙𝑒𝑐𝑡𝑟𝑖𝑐𝑎𝑙 𝐸𝑛𝑒𝑟𝑔𝑦𝑔𝑦
𝑀𝑒𝑐ℎ𝑎𝑛𝑐𝑖𝑎𝑙 𝐸𝑛𝑒𝑟𝑔𝑦
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Applications of Ferroelectric Materials

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 Applications

Use in Camera Flash

Ferroelectrics are very useful for devices and are used in many different ways today. If a
ferroelectric is used in its linear region, above TC it makes a very good capacitor, as its dielectric
constant can be very high indeed. These are often used in cameras as a way of powering a flash.

A battery slowly stores a charge on a capacitor, which when connected to a bulb, releases a
burst of high current, creating the flash.

First, the battery charges the ferroelectric capacitor and then, once fully charged, the
ferroelectric is connected to the bulb and causes it to flash.

Source: https://www.doitpoms.ac.uk/tlplib/ferroelectrics/why.php
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 Sensors and Actuators

Source: Advances and challenges in impedance-based structural health monitoring (Research Gate) 76
 Energy Harvesting

Sidewalks

Shoes

Gyms and Work Places

Piezoelectric Tiles, Floor mats and Carpets

Mobile Keypads and Keyboards

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Other Applications

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