I'm not sure which book I read, because I just googled it. and I found some questions that are very similar but only different methods are used.MathematicalPhysicist said:
but I still don't understand how I plugged the Zonal Spherical Harmonics into itMathematicalPhysicist said:
At ##r=R## you get ##\varphi(R,\theta)=0##, plug ##r=R## into the Zonal Spherical harmonic and equate to zero. For ##\varphi(r=\infty,\theta)=0##, notice that only ##P_0(\cos\theta)## contribution here, since there's no dependence on ##\cos \theta## in the boundary conditions.Zaitul Hidayat said:but I still don't understand how I plugged the Zonal Spherical Harmonics into it
Classical electromagnetism is a branch of physics that studies the relationship between electric and magnetic fields, and their interactions with matter. It is based on the laws of electromagnetism developed by James Clerk Maxwell in the 19th century.
The fundamental equations of classical electromagnetism are Maxwell's equations, which describe the behavior of electric and magnetic fields. They include Gauss's law, which relates electric fields to electric charges, and Ampere's law, which relates magnetic fields to electric currents.
Classical electromagnetism explains light as an electromagnetic wave, with oscillating electric and magnetic fields perpendicular to each other. This theory was first proposed by Maxwell and has been supported by numerous experiments, such as the double-slit experiment.
Classical electromagnetism has many practical applications, including the generation and transmission of electricity, the operation of electronic devices, and the development of technologies such as radios, televisions, and computers. It is also used in medical imaging techniques such as MRI and in the study of materials through techniques like X-ray diffraction.
Classical electromagnetism is closely related to other branches of physics, such as classical mechanics and quantum mechanics. It provides a framework for understanding the behavior of charged particles and their interactions with electric and magnetic fields. It also plays a crucial role in the development of modern physics, as it was a major inspiration for the development of quantum mechanics.