Transcript Slide 1

An Introduction to Piezoelectricity
ดร.เอกพล ศิวพรเสถียร
Department of Electronics and
Telecommunication Engineering
King Mongkut’s University of
Technology Thonbury (KMUTT)
Thailand
Educational Background
BS in Double Major in Electrical Engineering and Materials Science Engineering
from University of California at Berkeley, CA USA
MS in Electrical Engineering from University of Wisconsin—Madison, WI USA
Ph.D in Electrical Engineering (Major) and Biomedical Engineering (Minor) from
University of Wisconsin—Madison, WI USA
Outlines
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History of Piezoelectricity
Structure
What Can Piezoelectric Ceramics Do?
The Piezoelectric Effect
The Piezoelectric Constants
Motor Transducer Relationships
Generator Transducer Relationships
The Resonant Frequency
Piezoelectric Modes of Vibration
Applications
Examples
Concluding Remarks
Motivations
Motivations
Piezoelectricity: A History
 In 1880, Jacques and Pierre Curie discovered an unusual characteristic of
certain crystalline minerals: when subjected to a mechanical force, the crystals
became electrically polarized.
Tension and compression generated voltages of opposite polarity, and in
proportion to the applied force.
 Subsequently, the converse of this relationship was confirmed: if one of these
voltage-generating crystals was exposed to an electric field it lengthened or
shortened according to the polarity of the field, and in proportion to the
strength of the field.
These behaviors were labeled the piezoelectric effect and the inverse
piezoelectric effect, respectively, from the Greek word piezein, meaning to
press or squeeze.
 A traditional piezoelectric ceramic is a mass of perovskite crystals, each
consisting of a small, tetravalent metal ion, usually titanium or zirconium, in a
lattice of larger, divalent metal ions, usually lead or barium, and O2- ions
on the crystals, each crystal has a dipole moment
The perovskite structure is adopted by many oxides that have the chemical
formula ABO3. In the idealized cubic unit cell of such a compound, type 'A' atom
sits at cube corner positions (0, 0, 0), type 'B' atom sits at body centre position
(1/2, 1/2, 1/2) and oxygen atoms sit at face centred positions (1/2, 1/2, 0).
 Examples: metal oxide-based piezoeletric ceramics such as the lead zirconate
PbZrO3, lead tinanium PbTiO3 compounds, PZT (lead zirconate titanate).
At temperature above Curie point
 Above critical temperature, the Curie point, the crystal exhibits a simple
cubic symmetry with no dipole moment.
 At temperature below Curie point, however, each crystal has tetragonal or
rhombohedral symmetry and a dipole moment.
 Adjoining dipoles form regions of local alignment called domains.
 The alignment gives a net dipole moment to the domain, and thus polarization
 The domains in a ceramic element are aligned by exposing the element to a
strong, direct current electric field.
 When the electric field is removed, most of the dipoles are locked into a
configuration of near alignment.
What can piezoelectric ceramics do?
 The generator– mechanical energy converted into electrical energy
-- fuel igniting devices, solid state batteries, force-sensing device
 The motor – electrical energy converted into mechanical energy
-- piezoelectric motors, sound or ultrasound generating devices.
The Piezoelectric Effect
Review concepts of stress (T) and strain (S)
In materials science, the strength of a
material is its ability to withstand an applied
stress without failure. The applied stress may
be tensile, compressive, or shear.
Uniaxial stress is expressed by
T = F/A
where F is the force [N] acting on an area A [m2].
The Piezoelectric Effect
Strain is the geometrical measure of deformation. It measures how much a
given displacement differs locally from a rigid-body displacement.
Strain defines the amount of stretch or compression along a material line elements
or fibers, the normal strain, and the amount of distortion associated with the
sliding of plane layers over each other, the shear strain, within a deforming body.
S = L/L0
Strain is a dimensionless quantity, which can be expressed as a decimal fraction,
a percentage or in parts-per notation. This could be applied by elongation,
shortening, or volume changes, or angular distortion.
The Piezoelectric Effect
The slope of this line is also known as “Young’s Modulus” or “Modulus of
Elasticity”.
The Piezoelectric Effect
The experiments performed by the Curie brothers demonstrated that the
surface density of the generated linked charge was proportional to the
pressure asserted, and would disappear with it.
Pp = dT
where Pp is the piezopolarization vector, whose magnitude is equal to the
linked charge density by the piezoelectric effect
d is the piezoelectric strain coefficient
T is the stress to which the piezoelectric material is subjected.
The Piezoelectric Effect (cont.)
The reverse piezoelectric effect is also verified and demonstrated that the
ratio between the strain produced and the magnitude of the applied electric
field in the reverse effect, was equal to the ratio between the produced
polarization and the magnitude of the applied stress in the direct effect.
Sp = dE
where Sp is the strain produced by the piezoelectric effect,
E is the magnitude of the applied E field
Piezoelectric Constants
 Because a piezoelectric ceramic is anisotropic,
physical constants relate to both the direction
of the applied mechanical or electric force and
the directions perpendicular to the applied force.
 Thus, each constant generally has 2
subscripts.
Piezoelectric Charge Constant (d)
The piezoelectric charge constant, d, is the polarization generated per unit
mechanical stress (T) applied to a piezoelectric material OR
d is the mechanical strain (S) experienced by piezoelectric material per unit of
electric field applied.
d31 = induced polarization in direction 3 per unit stress applied in direction 1 OR
= induced strain in direction 1 per unit electric field applied in direction 3
Piezoelectric Voltage Constant (g)
is the electric field generated by a piezoelectric
material per unit of mechanical stress applied, OR
is the mechanical strain experienced by a
piezoelectric material per unit of electric
displacement applied.
g31 = induced electric field in direction 3 per unit stress applied in direction 1
= induced strain in direction 1 per unit electric displacement applied in
direction 3
Motor Transducer Relationships
Generator
Transducer
Relationships
The Resonant Frequencies
When exposed to an AC electric field, a piezoelectric ceramic element
changes dimensions cyclically, at the cycling frequency of the field.
The frequency at which the ceramic element vibrates most readily, and
most efficiently converts the electrical energy input into mechanical
energy, is the resonance frequency.
As the frequency of cycling is increased, the element's oscillations first approach
a frequency at which impedance is minimum (maximum admittance). This minimum
impedance frequency, fm , approximates the series resonance frequency, fs , the
frequency at which impedance in an electrical circuit describing the element is
zero,
The composition of the ceramic material and the shape and volume of the element
determine the resonance frequency -- generally, a thicker element has a lower
resonance frequency than a thinner element of the same shape.
As the cycling frequency is further increased, impedance increases to a
maximum (minimum admittance). The maximum impedance frequency, fn ,
approximates the parallel resonance frequency, fp , the frequency at which
parallel resistance in the equivalent electrical circuit is infinite. The maximum
impedance frequency also is the anti-resonance frequency, fa
Piezoelectric Ceramic’s Equivalent Circuit Model
Piezoelectric Modes of Vibration
Piezoelectric Modes of Vibration
Other Modes of Vibration
Several Modes of
A Plate Vibration
Applications
Piezoelectric devices fit into 4 general categories: generators, sensors,
actuators, and transducers.
 Generators: Piezoceramics can generate voltages sufficient to spark across
an electrode gap, and thus can as ignitors in fuel lighters, gas stove, welding
equipment. They are small and simple compared to their alternative systems
that use permanent magnet or high voltage inductors and capacitors.
Alternatively, the electrical energy generated by a piezoelectric element can
be stored. Techniques used to make multilayer capacitors have been used to
construct multilayer piezoelectric generators. Such generators are excellent
solid state batteries for electronic circuits.
 Sensors: A sensor converts a physical parameter such as acceleration or
pressure into an electrical signal. In some sensors, the physical parameter acts
acts directly on the piezoelectric element; in other devices an acoustical
signal establishes vibration in the element and the vibrations are, in turn,
converted into an electrical signal.
Applications (cont.)
 Actuators: A piezoelectric actuator converts an electrical signal into a
precisely controlled physical displacement, to finely adjust precision
machining tools, lenses, or mirrors.
Piezoelectric actuators also are used to control hydraulic valves, act as
small-volume pumps or special-purpose motors, and in other applications.
 Transducers: Piezoelectric transducers convert electrical energy into
vibrational mechanical energy, often sound or ultrasound, that is used to
perform a task. Piezoelectric transducers also are used to generate
ultrasonic vibrations for cleaning, atomizing liquids, drilling or milling
ceramics or other difficult materials, welding plastics, medical diagnostics,
or for other purposes.
Application Examples:
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Sonar
Nondestructive Testing (NDT)
Surface Acoustic Wave Sensors
Ultrasonic Nebulizer
Energy Harvesting System
…….. And many more!!
Underwater communication
The distance the wave travelled is estimated from the time of flight
Distance = c x t
where c is the speed of sound in medium
t is the time the wave travel
Speed of sound (in solid/liquid)
c
where E is the bulk modulus (N/m2)
 is the density (kg/m3)
Speed of sound (in air/gas)
c
E

 kT
m
Where  is the adiabatic index = 5/3 for monatomic molecule
k is the Boltzmann’s constant = 1.38x10-23 J/K
T is the temperature (K)
m is the mass of a single molecule in kg
NA is Avogadro’s number = 6.022x1023 per mole
Tactile sensor in touch screen panel
Atomization for
effective drug
delivery.
Surface Acoustic Wave (SAW) Device
 Sensor consists of a pair of input/output inter-digitated transducers (IDTs).
 SAWs of desired frequency can be generated from the input transducer,
travel on a piezoelectric substrate and be received by the output transducer.
 Upon detection of changes in material property along the path SAW travels,
the velocity of the wave would change. Consequently, the center frequency
shifts to a corresponding value.
Energy Harvesting System
 The piezoelectric films used for the energy generation are
constituted by a polymeric material coated in both sides by a
conducting material, which form the electrodes.
 The polymeric material is based on the polyvinylidene fluoride
(PVDF) polymer in its electroactive (β) phase.
Generators: harvesting energy from mechanical vibration to power small
low-power electronic devices such as a spy cam
Piezoelectric Energy Harvesting System
~
Full-bridge rectifier
Buck-boost DC/DC converter
Concluding Remarks
 Piezoelectric materials when subjected to a mechanical force, the crystals
became electrically polarized.
 Tension and compression generated voltages of opposite polarity, and in
proportion to the applied force.
 The effect is reversible: if the material is exposed to an electric field, it
lengthened or shortened according to the polarity of the field, and in proportion
to the strength of the field.
 When exposed to an AC electric field, a piezoelectric ceramic element
changes dimensions cyclically, at the cycling frequency of the field.
The frequency at which the ceramic element vibrates most readily, and
most efficiently converts the electrical energy input into mechanical
energy, is the resonance frequency.
 Main applications are generators, sensors, actuators, and transducers.
The End …(for now)