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A dimensionless physical quantity, on the other hand, has no dimensional unit as no dimension is involved. Consider the case of reynold’s number. It is a number without unit. However, there are exceptions. Consider measure of angle. It is a dimensionless quantity, but has radian as unit.

Basic dimensions and their group

Each of the basic dimensions form a group in dimensional formula. Consider a physical quantity work. The work is product of force and displacement. The basic dimension “length” is present in both force and displacement. Dimension in length, therefore, forms a group – one from force and one from displacement. The dimensions in the group is operated by multiplication following rule of indices x n x m = x m + n .

Determining dimensional formula

The basic approach to determine dimensional formula of a physical quantity is to use its defining equation. A defining equation like that of force in terms of mass and acceleration allows us to determine dimensional formula by further decomposing dependent quantities involved. This is the standard way. However, this approach is cumbersome in certain cases when dependencies are complicated. In such cases, we can take advantage of the fact that a physical quantity may appear in simpler relation in some other context. Let us consider the case of magnetic field strength. We can determine its dimensional expression, using Biot-Savart’s law. But, we know that Magnetic field strength appears in the force calculation on a wire carrying current in a magnetic field. The force per unit length :

F l = B I t

[ B ] = [ F ] [ A L T ] = [ M L T - 2 ] [ A L T ] = [ M T - 2 A - 1 ]

Problem : Find the dimensional formula of thermal conductivity.

Solution : The thermal heat of conduction (Q) is given as :

Q = k A θ 2 θ 1 t d

where “k” is thermal conductivity, “Q” is heat, “A” is area of cross-section, “θ” is temperature and “t” is time.

[ k ] = [ Q d ] [ A θ 2 θ 1 t ]

We make use of two facts (i) heat is energy and (ii) dimension of difference of temperature is same as that of temperature.

[ k ] = [ M L 2 T - 2 ] [ L ] [ L 2 K T ]

[ k ] = [ M L T - 3 K - 1 ]

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Problem : Find the dimension of expression,

C V ε 0 ρ

where “C” is capacitance, “V” is potential difference, “ ε 0 ” is permittivity of vacuum and “ρ” is specific resistance.

Solution :

By inspection of expression, we observe that capacitance of parallel plate capacitor is given by the expression containing “ ε 0 ”. This may enable us to cancel “ ε 0 ” from the ratio. The capacitance is given as :

C = ε 0 A d

On the other hand, specific resistance,

ρ = R A L

Hence,

[ C V ε 0 ρ ] = [ ε 0 A L V ] [ ε 0 d R A ]

Applying Ohm’s law,

[ C V ε 0 ρ ] = [ ε 0 A L V ] [ ε 0 L R A ] = [ V ] [ R ]

Applying Ohm's law,

[ C V ε 0 ρ ] = [ V ] [ R ] = [ A ]

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Problem : Find the dimension of term given as :

E 2 μ 0

where “E” is electric field and “ μ 0 ” is absolute permeability of vacuum.

Solution : We can approach the problem by evaluating each of the quantities in the expression terms of basic quantities. Alternatively, however, we can evaluate the dimension of the given ratio by expressing the given expression in terms of physical quantities, whose dimensions can be easily found out. For illustration purpose, we shall use the second approach.

Here we can write given expression in the following manner :

E 2 μ 0 = ε 0 E 2 ε 0 μ 0

where “ ε 0 ” is absolute permittivity of vacuum.

However, we know that electric energy density of a medium is 1 2 ε 0 E 2 . It means that numerator has the same dimension as “energy/volume”. On the other hand, speed of light in vacuum is given as :

c = 1 ε 0 μ 0

Thus, dimension of denominator is same as that of 1 c 2 .

Therefore,

E 2 μ 0 = [ energy/volume ] [ 1 c 2 ]

E 2 μ 0 = [ M L 2 T - 2 L 3 ] [ L T - 1 ] 2 = [ M L T - 4 ]

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Source:  OpenStax, Physics for k-12. OpenStax CNX. Sep 07, 2009 Download for free at http://cnx.org/content/col10322/1.175
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