About Piezoceramics
Piezoelectric ceramics are, after firing, composed of small grains (crystallites), each containing domains in which the electric dipoles are aligned. These grains and domains are randomly oriented, so the net electric dipole is zero, i.e. the ceramics do not exhibit piezoelectric properties.
The application of sufficiently strong D. C. field will orient the domains in the field direction, as nearly as the orientation of the crystal axes allows. This ability to change the orientation of the domains and achieve a net polarization is called ferroelectricity.
A remanent polarization can be created in ferroelectric ceramics by polarization. After the poling process is complete, a voltage with the same polarity as the poling voltage causes expansion along the poling axis and contraction perpendicular to the poling axis. Compressive or tensile forces applied to the ceramic element will generate a voltage.
Definitions and Terminology
In piezoelectric ceramics, material characteristics depend on the direction
of the applied field, displacement, stress and strain. Hence superscripts
and subscripts indicating the direction are added to the symbols.
The direction of polarization is generally designated as the z-axis of an orthogonal
crystallographic system. The axes x, y and z are respectively represented
as 1, 2 and 3 directions and the shear about these axes are represented
as 4, 5 and 6. This is shown schematically on the Symbols
and Terminoloy Chart. The various piezoelectric material constants
are generally expressed with subscripts using this notation. In addition
to the above, planar modes are sometimes expressed with a subscript
'p'.
Superscripts indicate a constant mechanical or electrical boundary condition.
The table below gives a general description of the superscripts.
| Parameter | Symbol | Condition |
| Stress | T | Mechanically free |
| Field | E | Electrical short circuit |
| Displacement | D | Electrical open circuit |
| Strain | S | Mechanically clampled |
Curie Temperature
The crystal structure of a material changes at the Curie temperature,
Tc, from piezoelectric (non-symmetrical) to a non-piezoelectric
(symmetrical) form. This phase change is accompanied by a peak in the
dielectric constant and a complete loss of all piezoelectric properties.
| A |
Surface area (m2) |
| c |
Stiffness coefficient (N/m2) |
| C |
Capacitance (F) |
| d |
Piezoelectric charge coefficient (C/N) |
| D |
Diameter (m) |
| f1, f2 |
-3dB points from the resonance frequency fr |
| fa |
Anti-resonance frequency (Hz) |
| fr |
Resonance frequency (HZ) |
| g |
Piezoelectric voltage coefficient (Vm/N) |
| k |
Coupling factor |
| K |
Relative dielectric constant |
| L |
Length (m) |
| N |
Frequency constant (Hz*m) |
| Q |
Mechanical Q factor |
| s |
Elastic compliance (m2/N) |
| T |
Thickness (m) |
| Tc |
Curie temperature (oC) |
| W |
Width (m) |
| Y |
Youngıs modulus (N/m2) |
| Zm |
Minimum impedance at fr (ohm) |
| tan δ |
Dissipation factor |
| εo |
Permittivity of free space (8.854x10-12F/m) |
| εT |
Permittivity (F/M) |
| ν |
Sonic velocity (m/s) |
| ρ |
Density (kg/m3) |
| σE |
Poisson's ratio |
