 11.1P: Check that the retarded potentials of an oscillating dipole (Eqs. 1...
 11.2P: Equation 11.14 can be expressed in “coordinatefree” form by writin...
 11.3P: Find the radiation resistance of the wire joining the two ends of t...
 11.4P: A rotating electric dipole can be thought of as the superposition o...
 11.5P: Calculate the electric and magnetic fields of an oscillating magnet...
 11.6P: Find the radiation resistance (Prob. 11.3) for the oscillating magn...
 11.7P: Use the “duality” transformation of Prob. 7.64, together with the f...
 11.8P: A parallelplate capacitor C, with plate separation d, is given an ...
 11.9P: Apply Eqs. 11.59 and 11.60 to the rotating dipole of Prob. 11.4. Ex...
 11.10P: An insulating circular ring (radius b) lies in the xy plane, center...
 11.11P: A current I (t) flows around the circular ring in Fig. 11.8. Derive...
 11.12P: An electron is released from rest and falls under the influence of ...
 11.13P: A positive charge q is fired headon at a distant positive charge Q...
 11.14P: In Bohr’s theory of hydrogen, the electron in its ground state was ...
 11.15P: Find the angle ?max at which the maximum radiation is emitted, in E...
 11.16P: In Ex. 11.3 we assumed the velocity and acceleration were (instanta...
 11.17P: (a) A particle of charge q moves in a circle of radius R at a const...
 11.19P: With the inclusion of the radiation reaction force (Eq. 11.80), New...
 11.20P: Deduce Eq. 11.100 from Eq. 11.99. Here are three methods:(a) Use th...
 11.21P: An electric dipole rotates at constant angular velocity ? in the x ...
 11.22P: A particle of mass m and charge q is attached to a spring with forc...
 11.23P: A radio tower rises to height h above flat horizontal ground. At th...
 11.24P: As a model for electric quadrupole radiation, consider two opposite...
 11.25P: As you know, the magnetic north pole of the earth does not coincide...
 11.27P: In Section 11.2.1 we calculated the energy per unit time radiated b...
 11.28P: Suppose the (electrically neutral) yz plane carries a timedependen...
 11.29P: Use the duality transformation (Prob. 7.64) to construct the electr...
 11.30P: Assuming you exclude the runaway solution in Prob. 11.19, calculate...
 11.31P: (a) Repeat Prob. 11.19, but this time let the external force be a D...
 11.32P: A charged particle, traveling in from ??along the x axis, encounter...
 11.33P: (a) Find the radiation reaction force on a particle moving with arb...
 11.34P: (a) Does a particle in hyperbolic motion (Eq. 10.52) radiate? (Use ...
Solutions for Chapter 11: Introduction to Electrodynamics 4th Edition
Full solutions for Introduction to Electrodynamics  4th Edition
ISBN: 9780321856562
Solutions for Chapter 11
Get Full SolutionsSince 32 problems in chapter 11 have been answered, more than 54539 students have viewed full stepbystep solutions from this chapter. This textbook survival guide was created for the textbook: Introduction to Electrodynamics , edition: 4. This expansive textbook survival guide covers the following chapters and their solutions. Chapter 11 includes 32 full stepbystep solutions. Introduction to Electrodynamics was written by and is associated to the ISBN: 9780321856562.

//
parallel

any symbol
average (indicated by a bar over a symbol—e.g., v¯ is average velocity)

°C
Celsius degree

°F
Fahrenheit degree