Piezoelectric crystals
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PIEZOELECTRIC PIEZOELECTRIC
CRYSTALSCRYSTALS
By By
ARILESERE FATIU .OARILESERE FATIU .O
Matric Number: Matric Number: 04/25OC01304/25OC013
Department of Science Education (Edu-Tech)Department of Science Education (Edu-Tech)
University of IlorinUniversity of Ilorin
CRYSTALSCRYSTALS
By By
ARILESERE FATIU .OARILESERE FATIU .O
Matric Number: Matric Number: 04/25OC01304/25OC013
Department of Science Education (Edu-Tech)Department of Science Education (Edu-Tech)
University of IlorinUniversity of Ilorin
Certain crystalline materials, namely,
Rochelle salt, Quartz and Tourmaline
exhibits the piezoelectric effect i.e. when
we apply an a.c voltage across them, they
vibrate at the frequency of the applied
voltage. Conversely, when they are
compressed or placed under mechanical
strain to vibrate, they produce and a.c
voltage.
Rochelle salt, Quartz and Tourmaline
exhibits the piezoelectric effect i.e. when
we apply an a.c voltage across them, they
vibrate at the frequency of the applied
voltage. Conversely, when they are
compressed or placed under mechanical
strain to vibrate, they produce and a.c
voltage.
Such crystals which exhibit piezoelectric
effect are known as piezoelectric crystals.
Of the various piezoelectric crystals, the
most commonly used is the quartz crystal.
This is because it is in-expensive and
readily available in nature.
effect are known as piezoelectric crystals.
Of the various piezoelectric crystals, the
most commonly used is the quartz crystal.
This is because it is in-expensive and
readily available in nature.
Quartz crystalQuartz crystal
Quartz crystals are
generally used in
crystal oscillator
because of their great
mechanical strength
and simplicity. The
shape of the quartz
crystal is hexagonal
as shown in fig.1.0.
•Fig.1.0
Z-Axis
Y-Axis
X-Axis
Quartz crystals are
generally used in
crystal oscillator
because of their great
mechanical strength
and simplicity. The
shape of the quartz
crystal is hexagonal
as shown in fig.1.0.
•Fig.1.0
Z-Axis
Y-Axis
X-Axis
Quartz Crystal in its structure has three axes
which are:
the Z-axis known as the optical axis,
the X-axis known as the electrical axis and
the Y-axis known as the mechanical axis as
shown above in fig.1.0 . The piezoelectric
properties of a crystal depend upon its cuts.
which are:
the Z-axis known as the optical axis,
the X-axis known as the electrical axis and
the Y-axis known as the mechanical axis as
shown above in fig.1.0 . The piezoelectric
properties of a crystal depend upon its cuts.
Frequenency of crystal Frequenency of crystal
Each crystal has a natural frequency like pendulum. The
natural frequency f of a crystal is given by:
F=k/t
Where k is the constant that depends upon the cuts and
t is the thickness of the crystal.
Therefore, the frequency f is inversely proportional to the
crystal thickness. The thinner the crystal, the greater its
natural frequency and vice-versa. However, extremely
thin crystal may break due to vibrations. This puts a limit
to the frequency obtainable. In practice, frequencies
between 25 kHz to 5 MHz have been obtained with
crystals.
Each crystal has a natural frequency like pendulum. The
natural frequency f of a crystal is given by:
F=k/t
Where k is the constant that depends upon the cuts and
t is the thickness of the crystal.
Therefore, the frequency f is inversely proportional to the
crystal thickness. The thinner the crystal, the greater its
natural frequency and vice-versa. However, extremely
thin crystal may break due to vibrations. This puts a limit
to the frequency obtainable. In practice, frequencies
between 25 kHz to 5 MHz have been obtained with
crystals.
Working with a quartz crystalWorking with a quartz crystal
In order to use crystal in an electronic circuit, it is
placed between two metal plates. The
arrangement forms a capacitor with the crystal
as the dielectric as shown in fig.1.1 below. If an
a.c voltage is applied across the plates, the
crystal will start vibrating at the frequency of the
applied voltage. However, if the frequency of the
applied voltage is made equal to the natural
frequency of the crystal, resonance takes place
and crystal vibrations reach a maximum value.
In order to use crystal in an electronic circuit, it is
placed between two metal plates. The
arrangement forms a capacitor with the crystal
as the dielectric as shown in fig.1.1 below. If an
a.c voltage is applied across the plates, the
crystal will start vibrating at the frequency of the
applied voltage. However, if the frequency of the
applied voltage is made equal to the natural
frequency of the crystal, resonance takes place
and crystal vibrations reach a maximum value.
This natural
frequency is almost
constant. Effect of
temperature can be
controlled by
mounting the crystal
in a temperature-
controlled oven as in
radio and television
transmitter.
•Fig1.1
Crystal
frequency is almost
constant. Effect of
temperature can be
controlled by
mounting the crystal
in a temperature-
controlled oven as in
radio and television
transmitter.
•Fig1.1
Crystal
Equivalent circuit of crystalEquivalent circuit of crystal
Although crystal has
electromagnetic
resonance, we can
represent the crystal
action by an equivalent
electrical circuit.
When a crystal is not
vibrating, it is equivalent
to capacitance (Cm)
because it has two metal
plates separated by a
dielectric as shown in
fig.1.2 (i). This
capacitance is known as
“Mounting Capacitance”.
Fig1.2 (i)
Cm
Although crystal has
electromagnetic
resonance, we can
represent the crystal
action by an equivalent
electrical circuit.
When a crystal is not
vibrating, it is equivalent
to capacitance (Cm)
because it has two metal
plates separated by a
dielectric as shown in
fig.1.2 (i). This
capacitance is known as
“Mounting Capacitance”.
Fig1.2 (i)
Cm
When a crystal vibrates
it is equivalent to R-L-C
series circuit. Therefore,
the equivalent circuit of
a vibrating crystal which
is the R-L-C series
circuit, is shunted by the
mounting capacitance
as shown in fig.1.2 (ii).
Where L is the electrical
equivalent of crystal
mass
C is the electrical
equivalent of elasticity
and
R is the electrical
equivalent of mechanical
friction.
fig.1.2 (ii)
Cm
L
R
C
it is equivalent to R-L-C
series circuit. Therefore,
the equivalent circuit of
a vibrating crystal which
is the R-L-C series
circuit, is shunted by the
mounting capacitance
as shown in fig.1.2 (ii).
Where L is the electrical
equivalent of crystal
mass
C is the electrical
equivalent of elasticity
and
R is the electrical
equivalent of mechanical
friction.
fig.1.2 (ii)
Cm
L
R
C
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