Given an aluminum disc of radius R, thickness d, conductivity , and mass density spins on its axis with initial velocity . It passes through poles of a magnet producing a magnetic field perpindicular to the disc over a small area A. With this initial speed how many revolutions will it make before coming to rest?
Potential at the center of a dielectric sphere
Determine the potential at the center of a dielectric sphere with dielectric constant K, radius R, and an embedded uniform charge density rho.
1. Consider a parallel plate capacitor, fixed area A, and fixed separation, d. Find the energy stored, and after insertion of a slab of dielectric, which completely fills the space between the plates for each of the two cases (a) The plates are connected to a battery which maintains constant potential difference (b) The pl ...continues
Consider a parallel plate capacitor with area A and separation d. The plates have fixed charges Q and -Q, and no battery connected. Determine the energy stored before and after the insertion of a dielectric with dielectric constant K that completely fills the space between the plates.
Two identical uniform sheet charges...
(See attached file for full problem description with all symbols) -- Two identical uniform sheet charges with =100nC/m2 are located in free space at z = + and - 2.0 cm . What force per unit area does each sheet exert on the other?
Problem 1.53 from Chapter 1, Introduction to Electrodynamics, 3rd edition, David J. Griffiths
Problem 1.53 from Chapter 1, Introduction to Electrodynamics, 3rd edition, David J. Griffiths See attached for full problem description.
Problem 1.54 from Chapter 1, Introduction to Electrodynamics, 3rd edition, David J. Griffiths
Problem 1.54 from Chapter 1, Introduction to Electrodynamics, 3rd edition, David J. Griffiths See attached for full problem description.
Problem 1.55 from Chapter 1, Introduction to Electrodynamics, 3rd edition, David J. Griffiths
Problem 1.55 from Chapter 1, Introduction to Electrodynamics, 3rd edition, David J. Griffiths See attached for full problem description.
Problem 1.58 from Chapter 1, Introduction to Electrodynamics, 3rd edition, David J. Griffiths
Problem 1.58 from Chapter 1, Introduction to Electrodynamics, 3rd edition, David J. Griffiths See attached for full problem description.
(See attached file for full problem description)
