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Maxwell's Equations: Assignment | Electricity & Magnetism - Physics PDF Download

Q.1. A uniform magnetic field in the positive z -direction passes through a circular wire loop of radius 1 cm and resistance 3.14Ω lying in the xy-plane. The field strength is reduced from 10 tesla to 9 tesla in 1s . Find the charge transferred across any point in the wire.

Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics


Q.2. The circuit shown below is in a uniform magnetic field that is into the page and is decreasing in magnitude at the rate of 150 Tesla/sec. Then find the ammeter reading.

Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics

From Ohm’s Law V - ε = IR , one can obtain the current. (Note that V = 5.0 V is the voltage of the battery. The voltage induced acts to oppose this emf from the battery). 

The problem gives dB/dt = 150T/s. The area is just 0.01 m2.
Thus, the induced emf is ε = dB/dt A = 150 x 0.01 = 1.5
Thus, V - e = 3.5 = IR ⇒ I = 0.35 A, since R = 10Ω.


Q.3. A rectangular loop of dimension L and width w moves with a constant velocity v away from an infinitely long straight wire carrying a current I in the plane of the loop as shown in the figure below. Let R be the resistance of the loop. Show that the current in the loop at the instant the near side is at a distance r from the wire is Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics

Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics


Q.4. The x and z -components of a static magnetic field in a region are Bx = B0 (x2- y2) and Bz = 0, respectively. Find one of the possible solution for its y -component which is consistent with the Maxwell equations?

Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics


Q.5. A parallel plate air-gap capacitor is made up of two plates of area 10cm2 each kept at a distance of 0.88 mm. A sine wave of amplitude 10V and frequency 50Hz is applied across the capacitor as shown in the figure.
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics(a) Find the amplitude of the displacement current density between the plates.
(b) Find the r.m.s value of the displacement current density between the plates.
(c) Find the average value of the displacement current density (in mA/m2) between the plates.

Displacement current density
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
(a) Amplitude of the displacement current density
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
(b) The r.m.s value of the displacement current density is
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
(c) The average value of the displacement current density is zero.


Q.6. Which of the following expressions represent an electric field due to a time varying magnetic field?
(a) Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
(b) Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
(c) Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
(d) Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics

For time varying fields Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
(a)
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
(b)
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
(c)
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
(d)
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics


Q.7. A coil of 15 turns, each of radius 1 centimeter, is rotating at a constant angular velocity ω=300 radians per second in a uniform magnetic field of 0.5 tesla, as shown in the figure. Assume at time t = 0 that the normal Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics to the coil plane is along the y -direction and that the self-inductance of the coil can be neglected. If the coil resistance is 9 ohms, what will be the magnitude of the induced current in milliamperes?
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics

The voltage induced is equal to the change in magnetic flux
 Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Noting the initial condition (ϕ(t = 0) = 0) , since the field and area normal are perpendicular). One finds that Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Thus, Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Now, to find the current, one uses Ohm’s Law in Faraday’s Law to get
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics where N is the number of turns.
Thus,
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Ampere
I = 25π cos (ωt) mA


Q.8. Consider a capacitor placed in free space, consisting of two concentric circular parallel plates of radii r. The separation z between the plates oscillates with a constant frequency ω, i.e. z(t )= z0 +z1 cosωt. Here z0 and z(< z0) are constants. The separation z(t )(<< r ) is varied in such a way that the voltage V0 across the capacitor remains constant.
(a) Calculate the displacement current density and the displacement current between the plates through a concentric circle of radius r/2.
(b) Calculate the magnetic field vector Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics between the plates at a distance r/2 

from the axis of the capacitor.

Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics(a) If the capacitor plates are very close together, then the electric field between them is:
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Displacement current density
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Displacement current
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
(b) Consider an amperian loop of radius r /2,
where,
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics


Q.9. A square loop of side L and mass M is made of a wire of cross-sectional area A and resistance R. The loop, moving with a constant velocity Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics in the horizontal xy-plane, enters a region 0 ≤ x ≤ 2L having constant magnetic field Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics .

Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics

Find an expression for the x-component of the force Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics acting on the loop in terms of its velocity Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics B,L and R.


Maxwell`s Equations: Assignment | Electricity & Magnetism - PhysicsInitial flux ϕ0= BLx
Flux after time dt, ϕ = BL(x + dx)
Change in flux dϕ = ϕ - ϕ0 = BLdx.
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics


Q.10. A small loop of wire of area A = 0.01m2, N = 40 turns and resistance R = 10Ω is initially kept in a uniform magnetic field B in such a way that the field is normal to the loop. When it is pulled out of the magnetic field, a total charge of Q = 2x10-5C flows through the coil. Find the magnitude of the field B.

Magnetic flux through the loop ϕ = NBA
Induced e.m.f ε = - dϕ/dt and induced current Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics
Thus
Maxwell`s Equations: Assignment | Electricity & Magnetism - Physics

The document Maxwell's Equations: Assignment | Electricity & Magnetism - Physics is a part of the Physics Course Electricity & Magnetism.
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FAQs on Maxwell's Equations: Assignment - Electricity & Magnetism - Physics

1. What are Maxwell's equations?
Ans. Maxwell's equations are a set of four fundamental equations that describe the behavior of electric and magnetic fields. They were formulated by James Clerk Maxwell in the 19th century and are widely used in the field of electromagnetism.
2. What is the importance of Maxwell's equations?
Ans. Maxwell's equations play a crucial role in understanding and predicting the behavior of electromagnetic waves and fields. They provide a complete and consistent framework for describing electric and magnetic phenomena, including the propagation of light, the behavior of antennas, and the operation of electronic devices.
3. How do Maxwell's equations relate to the IIT JAM exam?
Ans. In the context of the IIT JAM exam, Maxwell's equations are an essential topic in the physics syllabus. Questions related to these equations can be expected in the exam, testing candidates' understanding of electromagnetic theory and its applications.
4. Can you briefly explain each of Maxwell's equations?
Ans. Certainly! Maxwell's equations consist of four equations: 1. Gauss's law for electric fields: It states that the electric flux through a closed surface is proportional to the total charge enclosed within the surface. 2. Gauss's law for magnetic fields: It states that the magnetic flux through a closed surface is zero, indicating that there are no magnetic monopoles. 3. Faraday's law of electromagnetic induction: It describes how a changing magnetic field induces an electric field. 4. Ampere's law with Maxwell's addition: It relates the circulation of the magnetic field around a closed loop to the electric current passing through the loop, including the effect of changing electric fields.
5. How can one apply Maxwell's equations to solve practical problems?
Ans. To solve practical problems using Maxwell's equations, one typically formulates the given problem in terms of these equations and then applies appropriate mathematical techniques and boundary conditions. This can involve using differential equations, vector calculus, and material properties to determine the behavior of electric and magnetic fields in various scenarios, such as the design of circuits, analysis of electromagnetic waves, or the optimization of antenna performance.
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