168 10 Multipole Potentials
cf. (8.81). This force can be written as the negative gradient ofqφ,viz.Fμ=−∇μqφ,
where
φ=Q
4 πε 01
r,
is the electrostatic potential. ForNchargesqi, located at positionsrithe correspond-
ing expression is
φ=1
4 πε 0∑N
i= 1qi
|r−ri|. (10.21)
The generalization to a continuous charge densityρ(r′)is the electrostatic potential
φ(r)given by the integral
φ(r)=1
4 πε 0∫
ρ(r′)
|r−r′|d^3 r′. (10.22)By analogy to the mass density, cf. Sect.8.3.2, the charge density can also be written
asρ(r′)=
∑
iqiδ(r
′−ri). Insertion of this expression for the charge density into(10.22) yields (10.21).
10.3.2 Expansion of the Electrostatic Potential
In the following, it is understood that the charge distribution is centered aroundr′= 0
and thatris a point further away from this center than any of the charges generating
the electrostatic potential, cf. Fig.10.1.
So it makes sense to expand|r−r′|−^1 , occurring in (10.22), aroundr′=0.
Due to
∂
∂rμ′|r−r′|−^1 =−∂
∂rμ|r−r′|−^1 ,the Taylor series expansion of|r−r′|−^1 reads
Fig. 10.1Charge cloud
centered aroundr′=0. The
pointris outside of the cloud