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Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics PDF Download

Q.1. (a) A static charge distribution gives rise to an electric field of the form Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics where α and R are positive constants. Find the charge contained within a sphere of radius R, centered at the origin.
(b) An electric field Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics exists in space. What will be the total charge enclosed in a sphere of unit radius centered at the origin?

(a)
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
(b) 
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics


Q.2. A thin, nonconducting ring of radius R, as shown below, which has a charge Q uniformly spread out on it.
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
(a) At what distance x electric field, calculated directly above the center of the loop, is maximum.
(b) Find the electric potential at a point P, which is located on the axis of symmetry a distance x from the center of the ring.
(c) A small particle of mass m and charge -q is placed at point P and released. If R>>x, the particle will undergo oscillations along the axis of symmetry then find its angular frequency.

(a)
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
For maximum E,
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
(b) The electric field at point P is
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Recall the elementary equations,
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
(c)
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Small oscillations have the same form as simple harmonic oscillations, i.e, Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
The angular frequency is
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics


Q.3. A closed Gaussian surface consisting of a hemisphere and a circular disc of radius R, is placed in a uniform electric field Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics, as shown in the figure. The circular disc makes an angle θ = 30º with the vertical. Find the flux of the electric field vector coming out of the curved surface of the hemisphere.
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - PhysicsCoulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
OR
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics


Q.4. Three charges, each equal to 2q, are placed at the three corners (A, B and C) of a square of side 2a. Find the magnitude and directions of electric field at the fourth corner D.

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
 Electric field due to charge at A
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Electric field due to charge at C,
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Electric field due to charge at D,
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Resultant along x-direction is
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Resultant along x-direction is
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Thus magnitude of resultant field is
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics and direction along field EB .


Q.5. (a) For an infinitely long wire with uniform line-charge density, λ along the z -axis, find the electric field at a point ( a, b, 0 ) away from the origin.
(b) A uniform line charge, infinite in extent, having charge per unit length 10 nC/m lies along the z -axis. Find the magnitude of electric field Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics at ( 6, 8, 3) m.

(a)
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
(b)
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics


Q.6. A solid sphere of radius R has a charge density, given by
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
where r is the radial coordinate and ρ0 , a and R are positive constants.
(a) Find the magnitude of the electric field at r = R/2
(b) Find the magnitude of the electric field at r =R
(c) At what radial distance r, magnitude of the electric field is maximum. Also find the maximum electric field.
(d) If the magnitude of the electric field at r = R/2 is 1.25 times that at r = R , then find the value of a.

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
(a) The electric field at r
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
(b) The electric field at r
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
(c) For maximum electric field
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Thus maximum value is
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
(d)
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics


Q.7. Three charges are located on the circumference of a circle of radius R as shown in the figure below. The two charges q subtends an angle 90° at the centre of the circle. The charge Q is symmetrically placed with respect to the charges q.
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics(a) If Q = q, then find the magnitude and direction of electric field at centre O.
(b) If Q = 2q, then find the magnitude and direction of electric field at centre O.

(a)
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - PhysicsIf Q = q ;
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Resultant of E1 and E2 is Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
∵ E12 > E3
Thus resultant field is Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics  in downward direction.
(b)
If Q = 2q ;
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Resultant of E1 and E2 is Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
∵ E12 < E3

Thus resultant field is Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics in upward direction


Q.8. Two large nonconducting sheets one with a fixed uniform positive charge and another with a fixed uniform negative charge are placed at a distance of 1 meter from each other. The magnitude of the surface charge densities are σ+ = 6.8μC/mfor the positively charged sheet and σ- = 4.3μC/m2 for the negatively charged sheet.
(a) What is the electric field in the region between the sheets?
(b) What is the electric field in the region outside the sheets?

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
(a) Electric field between the sheet is
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

(b) Electric field outside the sheet (towards right) is
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Electric field outside the sheet (towards left) is Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics


Q.9. In a coaxial cable, the radius of the inner conductor is 2mm and that of the outer one is 5 mm. The inner conductor is at a potential of 10V, while the outer conductor is grounded. Find the value of the potential at a distance of 3.5 mm from the axis.
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

∵∇2V = 0
In Cylindrical coordinate system,
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Thus 10 = Aln2+ B and 0 = Aln5 + B
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
⇒V(r = 3.5) = Aln3.5+ B = 3.8 V


Q.10. (a) The electrostatic potential V(x, y) in some region is given by V(x, y)=3x2-3y2. Find the charge density ρ. Find the x and y -component of the electric field at the origin.
(b) If the electrostatic potential V (r,θ,ϕ ) in a charge free region has the form V(r.θ.ϕ) = f(r) cosθ, then set up the second order differential equation in f(r).
(c) If the electrostatic potential in spherical polar coordinates is Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics where φand r0 are constants, then find the charge density at a distance r = r0.

(a)
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
(b) 
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
(c)
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
At a distance  r = r0,
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics


Q.11. A segment of a circular wire of radius R, extending from θ = 0 to π/2, carries a constant linear charge density λ . Find the electric field at origin O.
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
where
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
and
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

Similarly
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics


Q.12. The plates of a parallel plate capacitor (which are normal to the x-axis) are located at  x = 0 and x = 2a . The plate at x = 0 is grounded while the other plate is at a potential V0. The space between the plates has uniform volume charge density ρ.
(a) Find the potential V(x) between the plates.
(b) Find the electric field E(x) between the plates.

(a) The Laplace’s equation in Cartesian coordinates system is
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physicsas V is only function of x , we have the differential equation, Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physicsby integrating we have the solution of this equation as Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics where A and B are constants. The two equations need to be solved for the following boundary conditions:(i) x = 0 ;V = 0
(ii) x = 2a; V= V0
Substituting these boundary conditions, we get
At x = 0 , V(0) = 0 = 0 = 0 + B ⇒ B = 0
At x = 2a,
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics(b)
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics


Q.13. Consider a sphere S1 of radius R which carries a uniform charge of density ρ. A smaller sphere S2 of radius a<R/2 is cut out and removed from it. The centres of the two spheres are separated by the vector Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics as shown in the figure. Find the electric field at a point P inside S2.
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - PhysicsElectric field at P due to S1 is Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Electric field at P due to 2 S (assume -ρ ) is Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Thus
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics


Q.14. The shape of a dielectric lamina is defined by the two curves y = 0 and y = 1-x2. If the charge density of the lamina is σ = 7.5yC/m2, then find the total charge on the lamina.

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - PhysicsTotal charge on the lamina is
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics


Q.15. The electrostatic potential due to a charge distribution is given by Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics where A and λ are constants.
a) Find the electric field.
(b) Find the total charge enclosed within a sphere of radius 1/λ, with its origin at r = 0.

(a)
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
(b)
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Thus total charge enclosed within a sphere of radius r = 1/λ is
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics


Q.16. Four equal charges of +Q each are kept at the vertices of a square of side R. A particle of mass m and charge +Q is placed in the plane of the square at a short distance a(<<R ) from the centre. If the motion of the particle is confined to the plane, it will undergo small oscillations then find its angular frequency.

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Resultant field E12,y = 2E1 cos θ
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

Similarly;
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

Resultant
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

Resultant
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics
Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics

The document Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment | Electricity & Magnetism - Physics is a part of the Physics Course Electricity & Magnetism.
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FAQs on Coulomb’s Law, Gauss Law and Electrostatic Potential: Assignment - Electricity & Magnetism - Physics

1. What is Coulomb's law?
Ans. Coulomb's law states that the force between two charged particles is directly proportional to the product of their charges and inversely proportional to the square of the distance between them. It is given by the equation F = k * (q1 * q2) / r^2, where F is the force, q1 and q2 are the charges, r is the distance, and k is the proportionality constant.
2. What is Gauss's law?
Ans. Gauss's law relates the electric flux flowing through a closed surface to the charge enclosed within that surface. It states that the electric flux through any closed surface is equal to the electric charge enclosed divided by the permittivity of free space. Mathematically, it can be written as Φ = Q / ε0, where Φ is the electric flux, Q is the charge enclosed, and ε0 is the permittivity of free space.
3. How is electrostatic potential defined?
Ans. Electrostatic potential is defined as the amount of work done in bringing a unit positive charge from infinity to a specific point in an electric field. It is a scalar quantity and is measured in volts. The electrostatic potential at a point is given by the equation V = k * (q / r), where V is the electrostatic potential, q is the charge, r is the distance, and k is the proportionality constant.
4. What is the relationship between electric potential and electric field?
Ans. The relationship between electric potential and electric field is given by the equation E = -∇V, where E is the electric field, V is the electric potential, and ∇ is the gradient operator. This equation states that the electric field is the negative gradient of the electric potential. In other words, the electric field points in the direction of decreasing potential.
5. How does the electric potential vary around a point charge?
Ans. The electric potential around a point charge varies inversely with the distance from the charge. As the distance increases, the electric potential decreases. Mathematically, the electric potential due to a point charge q at a distance r is given by the equation V = k * (q / r), where V is the electric potential, q is the charge, r is the distance, and k is the proportionality constant.
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