📖 generic · CBSE Class 12th English Medium · PHYSICS PART-1 · Page 37definition

along the radius vector at that point, the area element Δ S and ˆ r have

Chapter 1: Chapter 1 · PHYSICS PART-1

along the radius vector at that point, the area element Δ S and ˆ r have the same direction. Therefore, S φ Δ Δ ( . ) since the magnitude of a unit vector is . The total flux through the sphere is obtained by adding up flux through all the different area elements: FIGURE .

Flux through a sphere enclosing a point charge q at its centre. all S S φ Δ Σ Δ Since each area element of the sphere is at the same distance r from the charge, all S o S S φ Δ Σ Δ Now S , the total area of the sphere, equals π r . Thus, φ ( . ) Equation ( .

) is a simple illustration of a general result of electrostatics called Gauss’s law. We state Gauss’s law without proof: Electric flux through a closed surface S = q/ ε ( . ) q = total charge enclosed by S. The law implies that the total electric flux through a closed surface is zero if no charge is enclosed by the surface.

We can see that explicitly in the simple situation of Fig. . . Here the electric field is uniform and we are considering a closed cylindrical surface, with its axis parallel to the uniform field E .

The total flux φ through the surface is φ = φ + φ + φ , where φ and φ represent the flux through the surfaces and (of circular cross-section) of the cylinder and φ is the flux through the curved cylindrical part of the closed surface. Now the normal to the surface at every point is perpendicular to E , so by definition of flux, φ = . Further, the outward normal to is along E while the outward normal to is opposite to E . Therefore, φ = – E S , φ = + E S S = S = S where S is the area of circular cross-section.

Thus, the total flux is zero, as expected by Gauss’s law. Thus, whenever you find that the net electric flux through a closed surface is zero, we conclude that the total charge contained in the closed surface is zero. The great significance of Gauss’s law Eq. ( .

), is that it is true in general, and not only for the simple cases we have considered above. Let us note some important points regarding this law: (i) Gauss’s law is true for any closed surface, no matter what its shape or size. (ii) The term q on the right side of Gauss’s law, Eq. ( .

), includes the sum of all charges enclosed by the surface. The charges may be located anywhere inside the surface. (iii) In the situation when the surface is so chosen that there are some charges inside and some outside, the electric field [whose flux appears on the left side of Eq. ( .

)] is due to all the charges, both inside and outside S . The term q on the right side of Gauss’s law, however, represents only the total charge inside S . FIGURE . Calculation of the flux of uniform electric field through the surface of a cylinder.

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