By: Engr. Hinesh Kumar Lecturer I.B.T, LUMHS ELECTRIC FLUX & ELECTRIC FLUX DENSITY.

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Presentation transcript:

By: Engr. Hinesh Kumar Lecturer I.B.T, LUMHS ELECTRIC FLUX & ELECTRIC FLUX DENSITY

 In electromagnetism, electric flux is the rate of flow of the electric field through a given area.  The total number of lines of force passing through the unit area of a surface.  It is scalar quantity.  Its unit is N.m²/C or V.m ELECTRIC FLUX

 Mathematically the electric flux is defined as:  "The dot product of electric field intensity (E) and the vector area (∆A) is called electric flux.“  Where θ is angle between E and ∆A MATHEMATICALLY

PROPERTIES  Maximum Flux  If the surface is placed perpendicular to the electric field then maximum electric lines of force will pass through the surface. Consequently maximum electric flux will pass through the surface  line are perpendicular than θ=0

 Zero Flux  If the surface is placed parallel to the electric field then no electric lines of force will pass through the surface. Consequently no electric flux will pass through the surface. CONT...

 Consider a small positive point charge +q placed at the Centre of a closed sphere of radius "r".  The relation is not applicable in this situation because the direction of electric intensity varies point to point over the surface of sphere.  In order to overcome this problem the sphere is divided into a number of small and equal pieces each of area ∆A.  The direction of electric field in each segment of sphere is the same i.e. outward normal. ELECTRIC FLUX THROUGH A SPHERE

 Now we will determine the flux through each segment. Electric flux through the first segment:  But θ=0 CONT...

 Electric flux through the second segment:  Similarly, Electric flux through other segments: CONT…

 Being a scalar quantity, the total flux through the sphere will be equal to the algebraic sum of all these flux i.e.  But CONT…

 As (Area of sphere)  Then equation is  This expression shows that the total flux through the sphere is 1/e O times the charge enclosed (q) in the sphere. CONT…

 The Electric Flux Density is called Electric Displacement denoted by D, is a vector field that appears in Maxwell's equations.  It is equal to the electric field strength multiplied by the permittivity of the material through which the electric field extends.  It is measured in coulombs per square meter.  The Electric Flux Density (D) is related to the Electric Field (E) by: Equation (1) ELECTRIC FLUX DENSITY

 In Equation [1], ε is the permittivity of the medium (material) where we are measuring the fields.  If you recall that the Electric Field is equal to the force per unit charge (at a distance R from a charge of value q1 [C]) Equation (2)  Then the Electric Flux Density is: Equation (3) CONT…

 From Equation [3], the Electric Flux Density is very similar to the Electric Field, but does not depend on the material in which we are measuring (that is, it does not depend on the permittivity.  Note that the D field is a vector field, which means that at every point in space it has a magnitude and direction.  The Electric Flux Density has units of Coulombs per meter squared [C/m²]. CONT…