Try this...
- Arrange a simple set up as shown in
the diagram above. - The lamp will glow when circuit is
complete. - Prepare 5 % (mass/volume) solutions
of cane sugar, acetic acid, sodium
chloride and urea in distilled water. - Check the electrical conductivity
of these solutions using the above
assembly. Compare these with that
observed with distilled water.
i. The conducting and nonconducting
nature of solutions can be identified
by measurement of their conductivity.
Sucrose and urea do not dissociate in their
aqueous solutions. The conductivities of
these solutions are nearly the same as
that of water. These substances are called
nonelectrolytes.
On the other hand, substances like
potassium chloride, acetic acid, sodium
hydroxide, HCl dissociate in their aqueous
solutions. The conductivities of their
aqueous solutions are higher than that
of water. These are called electrolytes.
Electrolytes conduct electricity in molten
state or when dissolved in water.
ii. On the basis of high or low electrical
conductivity electrolytes are classified
into strong and weak electrolytes. The
substances such as ionic salts, strong
acids or bases are almost completely
dissociated in aqueous solutions. These
are strong electrolytes. The solutions
of strong electrolytes exhibit high
conductivities.
The weak acids and weak bases are
weak electrolytes. They dissociate to a
very small extent in aqueous solutions
and show lower conductivities than those
of strong electrolytes.
5.2.2 Electrolytic or ionic conduction :
Electrolytic conduction involves conduction
of electric current by the movement of ions
of the electrolytes. In this type of conduction
the charge transfer occurs in the form of
movement of ions through molten electrolytes
or the aqueous solutions of electrolytes.
Substances such as ionic salts, strong or weak
acids and bases are the electrolytes. These
dissociate into ions when dissolved in polar
solvents such as water. Ionic solids dissociate
into ions in molten state as well.
Conduction through electrolytic
conductors involves transfer of matter from
one part of the conductor to the other. It
means that the current flowing through an
electrolytic conductor is accompanied by a
chemical change.
5.2.3 Information provided by measurement
of conductivities of solutions :
Remember...
Electrolyte is a compound that
conducts electricity when molten or
in aqueous solution and breaks down into
ions during electrolysis.
5.3 Electrical conductance of solution :
According to Ohm's law, the electrical
resistance R of a conductor is equal to the
electric potential difference V divided by the
electric current, I :
R =
V
I^ (5.1)
The SI unit of potential is volt (V) and
that of current is ampere (A). The unit of
Switch Battery
Non conductive
frame
Electrodes
Solution
Lamp