Ohm's Law is the linear proportionality between current and voltage
that occurs for most conductors of electricity. A graph of voltage
against current is a straight line. The gradient is the resistance.
The most well known form of Ohm's law is V=IR, where V is the voltage, I is the current and R is the resistance. However there is another form of Ohm's law which often used by physicists that operates on a microscopic level, relating the current density J to the conductivity σ and the electric field, E.
To see how consider, the volume of material with faces of area A a distance l apart. With an e.m.f. V across the faces of the material
I = VAσ/l.
R = l/Aσ
The proportionality constant σ is the conductivity of the material.
V/l = |E|, and J = I/A in the direction of E so in general we have the constitutive relation.
J = σE
The most well known form of Ohm's law is V=IR, where V is the voltage, I is the current and R is the resistance. However there is another form of Ohm's law which often used by physicists that operates on a microscopic level, relating the current density J to the conductivity σ and the electric field, E.
To see how consider, the volume of material with faces of area A a distance l apart. With an e.m.f. V across the faces of the material
- the current is proportional to the voltage V
- the current is proportional to the surface area A
- and the current is inversely proportional to the distance l.
I = VAσ/l.
R = l/Aσ
The proportionality constant σ is the conductivity of the material.
V/l = |E|, and J = I/A in the direction of E so in general we have the constitutive relation.
J = σE
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