Piezoelectric Materials and Applications

Piezoelectric Material
(Future source of electricity)

Discovered in 1880 by French physicists Jacques and
Pierre Curie in quartz crystals.
The word originates from the greek word “piezein”,
which means “to press”.
If certain crystals were subjected to mechanical strain,
they became electrically polarized and the degree of
polarization was proportional to the applied strain.
Examples -- Quartz, Barium titanate, tourmaline e.t.c.

Animated representation of Piezoelectric Effect

• Piezoelectric behaviour can be manifested in
two distinct ways-
1. ‘Direct’ piezoelectric effect
2. ‘Converse’ piezoelectric effect
Types Of Piezoelectricity

Direct piezoelectric effect
• The electrical response to mechanical
stimulation is called the direct piezoelectric
effect.
• The devices based on this effect can be used
to detect strain, movement, force, pressure or
vibration by developing appropriate electrical
responses, as in the case of force and acoustic
or ultrasonic sensors.

Converse Piezoelectric Effect
• The mechanical response to electrical stimulation
is called the converse piezoelectric effect i.e.
when the piezoelectric material placed in an
electric field they becomes strained.
• This property can be used to generate strain,
movement, force, pressure or vibration through
the application of suitable electric field on
piezoelectric material.

Piezoelectric Materials and Applications

Piezoelectricity
Piezoelectricity is the ability
of certain materials
(piezoelectric materials) to
produce a voltage when
subjected to mechanical
stress.
Piezoelectric materials also
show the opposite effect,
where application of an
electrical field creates
mechanical stress (size
modification) in the crystal.

The effect is explained by the displacement of ions in crystals that
have a nonsymmetrical unit cell.
When the crystal is compressed, the ions in each unit cell are
displaced, causing the electric polarization of the unit cell.
Because of the regularity of crystalline structure, these effects
accumulate, causing the appearance of an electric potential difference
between certain faces of the crystal.
When an external electric field is applied to the crystal, the ions in
each unit cell are displaced by electrostatic forces, resulting in the
mechanical deformation of the whole crystal.
INTERNAL WORKING

Piezoelectric Material
• To exhibit piezoelectricity two main necessary
conditions are -
1. Crystal should have Ionic or partially Ionic bonds.
2. Its structure should have no centre of symmetry.
 Piezoelectric materials are usually divided into two
groups-
I. Hard Piezoelectric Materials
II. Soft Piezoelectric Materials
 The antonyms “hard” and “soft” doped piezoelectric
materials refer to the ferroelectric properties, i.e. the
mobility of the dipoles or domains and hence also to
the polarization/depolarization behaviour.

Some naturally occurring crystals
1. Quartz
2. Sucrose (table sugar)
3. Tourmaline-group minerals
4. Rochelle salt
5. Berlinite (AlPO4), a rare phosphate mineral that is
structurally identical to quartz
6. Topaz
7. Lead titanate (PbTiO3). Although it occurs in nature as
mineral macedonite, it is synthesized for research and
applications.
Many materials, both natural and synthetic, exhibit
piezoelectricity:

Other natural materials
Biological materials exhibiting piezoelectric properties
include:
1. Tendon
2. Silk
3. Wood (due to piezoelectric texture)
4. Enamel
5. Dentin
6. DNA
7. Dry Bone
8. Viral proteins, including those from bacteriophage. One
study has found that thin films of M13 bacteriophage can be
used to construct a piezoelectric generator sufficient to
operate a liquid crystal display.

Some synthetic crystals
1. Barium titanate (BaTiO3)—Barium titanate was the first
piezoelectric ceramic discovered.
2. Lead zirconate titanate (Pb[ZrxTi1−x]O3 , 0≤x≤1)—more
commonly known as PZT, the most common piezoelectric
ceramic in use today.
3. Gallium orthophosphate (GaPO4)
4. Langasite (La3Ga5SiO14)
5. Potassium niobate (KNbO3)
6. Lithium niobate (LiNbO3)
7. Lithium tantalate (LiTaO3)
8. Sodium tungstate (Na2WO3)
9. Ba2NaNb5O5
10. Pb2KNb5O15
11. Zinc oxide (ZnO) , Ceramics and polycrystalline thin film.

Principles of Application
1. Energy Conversion Mechanism - An externally applied
electric field causes a change in the dielectric
polarization in the material which in turn causes an
elastic strain. The generating action takes place when an
elastic strain causes a change in the polarization that
induces a charge on the electrodes.
2. Transducer Operating Environment -
• The acoustic properties of the medium (air, water or ice)
are very important in the design of transducers.
• Transducers must also withstand the severe effects of sea
water, biological activity, hydrostatic pressure, and
extreme temperature conditions.

3. Conversion Criteria – The following are the
general performance criteria for the transducers-
i. Linearity - The output of the transducer is a linear
function of the input.
ii. Reversibility - The transducer must convert energy
in either direction.
iii. Passivity - All the output energy from the
transducer is obtained from the input energy -
electrical or acoustical.

Application Of Piezoelectric Material
• Mechanical to Electrical
Conversion -
1. Phonograph cartridges
2. Microphones
3. Vibration sensors
4. Accelerometers
5. Photoflash actuators
6. Gas igniters
7. Fuses
• Electrical to Mechanical
Conversion –
1. Valves
2. Micropumps
3. Earphones and speakers
4. Ultrasonic cleaners
5. Emulsifiers
6. Sonic transducers
Piezoelectric material can be used by the application of
both “direct” as well as “converse” piezoelectric effect-

Piezoelectric device in various fields
Optics, Photonics and
Measuring Technology
• Image stabilization
• Scanning microscopy
• Auto focus systems
• Interferometry
• Fiber optic alignment &
switching
• Fast mirror scanners
• Adaptive and active optics
• Laser tuning
• Mirror positioning
• Holography
• Stimulation of vibrations
Disk Drive
• MR head testing
• Pole tip recession
• Disk spin stands
• Vibration cancellation
Microelectronics
• Nano-metrology
• Wafer and mask
positioning
• Critical Dimensions
measurement
• Microlithography
• Inspection systems
• Vibration
cancellation
Precision Mechanics and
Mechanical Engineering
• Vibration cancellation
• Structural deformation
• Out-of-roundness grinding,
drilling, turning
• Tool adjustment
• Wear correction
• Needle valve actuation
• Micro pumps
• Linear drives
• Piezo hammers
• Knife edge control in extrusion
tools
• Micro engraving systems
• Shock wave generation
Life Science, Medicine,
Biology
• Patch-clamp drives
• Gene technology
• Micro manipulation
• Cell penetration
• Micro dispensing
devices
• Audiophysiological
stimulation
• Shock wave generation

Sonar
First practical application of piezoelectric devices
used during WORLD WAR 1 in 1917

Daily use of piezoelectric device
Piezoelectric Igniters - Commercially, most common use is
as gas lighters. These are capable of producing a spark.

Medical Use
• Industrially, piezoelectric devices are mainly used for
imaging, mostly in medicine. They are used to
produce ultrasound, which is used to check on
unborn babies. In a non-medicinal manner, it can be
used to detect cracks.
Working Process In medical use

Typical Application-Combustion Monitoring
• Pressures developed
during the combustion
process is continuously
measured by sensors
mounted on the
cylinder heads.
• Continuous Pressure
monitor(CPM) systems
are the basic data
acquisition and data
reduction software and
hardware units.

Marine Mammal Listening Systems

Marine Mammal Listening Process

Recent Advances of Piezoelectric Material in Medical
• A recent application of piezoelectric ultrasound sources
is piezoelectric surgery, also known as piezosurgery.
• Piezosurgery is a minimally invasive technique that
aims to cut a target tissue with little damage to
neighboring tissues.
• For example - Hoigne et al. reported its use in hand
surgery for the cutting of bone, using frequencies in
the range 25–29 kHz, causing microvibrations of 60–
210 μm. It has the ability to cut mineralized tissue
without cutting neurovascular tissue and other soft
tissue, thereby maintaining a blood-free operating
area, better visibility and greater precision.

Recent Advances-
HARVESTING ENERGY FROM HUMANS
(Present use of technology)
 With the increase in energy consumption due to
evergrowing number of electronic devices, the concept of
harvesting renewable energy in human surrounding arouses
a renewed interest.
 Piezoelectric effect can be used to generate electricity
using such body energies to run smaller gadgets which
consume less power. With further advancement in field of
electronics, better synthesized piezoelectric crystals and
better selection of place of installations, more electricity can
be generated and it can be viewed as a next promising
source of generating electricity.

Special flooring tiles with piezoelectric
crystals to generate electricity

Specially designed road which generates
electricity

Dance floors with piezoelectric crystals
installed to produce electricity

Conclusion
• Use of piezoelectric crystals has being started
and positive results are obtained. With further
advancement in field of electronics, better
synthesized piezoelectric crystals and better
selection of place of installations, more
electricity can be generated and it can be
viewed as a next promising source of
generating electricity.

A special thanks to
Miss Astha Singh
(Guide of the project)

Piezoelectric Materials and Applications

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