A (physical) electric dipole consists of two equal and opposite charges (±q) separated by a distance d. Find the approximate potential at points far from the dipole.
Question 3.10: A (physical) electric dipole consists of two equal and oppos...
Let η− be the distance from −q and η+ the distance from +q (Fig. 3.26). Then
V(r)=\frac{1}{4\pi\epsilon _{0}}\left(\frac{q}{\eta +}-\frac{q}{\eta -} \right) ,and (from the law of cosines)
\eta ^{2}_{\pm}=r^{2}+(d/2)^{2}\mp rd\cos\theta =r^{2}\left(1\mp \frac{d}{r}\cos\theta+\frac{d^{2}}{4r^{2}} \right).We’re interested in the régime r\gg d , so the third term is negligible, and the binomial expansion yields
\frac{1}{\eta _{\pm }}\cong \frac{1}{r}\left(1\mp \frac{d}{r}\cos\theta \right)^{-1/2}\cong\frac{1}{r}\left(1\pm \frac{d}{2r}\cos\theta \right) .Thus
\frac{1}{\eta _\pm}-\frac{1}{\eta _{-}}\cong \frac{d}{r^{2}}\cos\theta,and hence
V(r)\cong \frac{1}{4\pi\epsilon _{0}}\frac{qd\cos\theta}{r^{2}}. (3.90)
The potential of a dipole goes like 1/r^ {2} at large r ; as we might have anticipated, it falls off more rapidly than the potential of a point charge. If we put together a pair of equal and opposite dipoles to make a quadrupole, the potential goes like 1/r^ {3}; for back-to-back quadrupoles (an octopole), it goes like 1/r^ {4}; and so on. Figure 3.27 summarizes this hierarchy; for completeness I have included the electric monopole (point charge), whose potential, of course, goes like 1/r .
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