"Particles", i.e. atoms or molecules in a liquid or solid are basking in electrical fields  the external field that we apply from the outside is not necessarily all they "see" in terms of fields.  
First, of course, there is a tremendous electrical field inside any atom. We have after all, positive charges and negative charges separated by a distance roughly given by the diameter of the atom.  
Second, we have fields between atoms, quite evident for ionic crystals, but also possible for other cases of bonding.  
However, if you look at the materials at a scale somewhat larger than the atomic scale, all these fields must average to zero. Only then do we have a fieldfree interior as we always assume in electrical engineering ("no electrical field can penetrate a metal").  
Here, however, we are looking at the effect an external field has on atoms and molecules, and it would be preposterous to assume that what an atom "sees" as local electrical field is identical to what we apply from the outside.  
Since all our equations obtained so far always concerned the local electrical field  even if we did not point that out in detail before  we now must find a relation between the external field and the local field, if we want to use the insights we gained for understanding the behavior of dielectrics on a macroscopic scale.  
We define the local field E_{loc} to be the field felt by one particle (mostly an atom) of the material at its position (x,y,z).  
Since the superposition principal for fields always holds, we may express E_{loc} as a superposition of the external field E_{ex} and some field E_{mat} introduced by the surrounding material. We thus have  


All electrical fields can, in principle, be calculated from looking at the charge distribution r(x, y, z) in the material, and then solving the Poisson equation (which you should know). The Poisson equation couples the charge distribution and the potential V(x, y, z) as follows:  


The electrical field then is just the (negative) gradient of the potential; E = – ÑV.  
Doing this is pretty tricky, however. We can obtain usable results in a good approximation in a much simpler way, by using the timehonored Lorentz approach or the Lorentz model.  
In this approach we decompose the total field into four components.  
For doing this, we imagine that we remove a small sphere containing a few 10 atoms from the material. We want to know the local field in the center of this sphere while it is still in the material; this is the local field E_{mat} we are after. We define that field by the force it exerts on a charge at the center of the sphere that acts as a "probe".  
The essential trick is to calculate the field produced from the atoms inside the sphere and the field inside the now empty sphere in the material. The total local field then is simple the sum of both.  
Like always, we do not consider the charge of the "probe" in computing the field that it probes. The cutout sphere thus must not contain the charge we use as the field probe!  
The cutout material, in general, could produce an electrical field at its center since it is composed of charges. This is the 1st component of the field, E_{near} which takes into account the contributions of the atoms or ions inside the sphere. We will consider that field in an approximation where we average over the volume of the small sphere. To make things clear, we look at an ionic crystal where we definitely have charges in our sphere.  
E_{near}, however, is not the only field that acts on our probe. We must include the field that all the other atoms of the crystal produce in the hollow sphere left after we cut out some material. This field now fills the "empty" void left by taking out our sphere.  
This field is called E_{L} (the "L" stands for Lorentz); it compensates for the cutout part  and that provides our 2nd component.  
Now we only have to add the "macroscopic" fields from 1. the polarization of the material and 2. the external field that causes everything:  
The field E_{pol} is induced by the macroscopic polarization (i.e. by area charges equal to the polarization); it is the 3rd component.  
The external field E_{ex} = U/d from the applied voltage at our capacitor which supplies the 4th component.  
In a visualization, this looks like this:  

The blue "sphere" cuts through the lattice (this is hard to draw). The yellow "point" is where we consider the local field; we have to omit the contribution of the charged atom there. We now have  


How large are those fields? We know the external field and also the field from the polarization (always assuming that the material completely fills the space inside the capacitor).  


We do not know the other two fields, and it is not all that easy to find out how large they are. The results one obtains, however, are quite simple:  
Lorentz showed that E_{near} = 0 for isotropic materials, which is easy to imagine. Thus for cubic crystals (or polycrystals, or amorphous materials), we only have to calculate E_{L}.  
E_{L} needs some thought. It is, however, a standard problem from electrostatics in a slightly different form.  
In the standard problem one calculates the field in a materials with a DK given by e_{r} that does not fill a rectangular capacitor totally, but is in the shape of an ellipsoid including the extreme cases of a pure sphere, a thin plate or a thin needle. The result is always  


In words: The field inside a dielectric in the shape of an ellipsoid (of any shape whatsoever) that is put between the parallel plates of a typical capacitor arrangement, is whatever it would be if the dielectric fills the space between the plates completely times a number N_{P}, the value of which depends on the geometry.  
N_{P} is the socalled
depolarization factor, a pure number, that only depends on the shape of the
ellipsoid. For the extreme cases of the ellipsoid we have fixed and wellknown
depolarization factors:


Our case consists of having a sphere with e_{r} = 1. We thus obtain  

We have now all components and obtain  


U/d – P/e_{0} is just the field we would use in the Maxwell equations, we call it E_{0}. It is the homogeneous field averaged over the whole volume of the homogeneous material  
The local
field finally becomes 



This seems a bit odd? How can the local field be different from the average field?  
This is one of the tougher questions one can ask. The answer, not extremely satisfying, comes from the basic fact that all dipoles contribute to E_{0}, whereas for the local field you discount the effect of one charge  the charge you use for probing the field (the field of which must not be added to the rest!).  
If you feel somewhat uneasy about this, you are perfectly right. What we are excluding here is the action of a charge on itself. While we may do that because that was one way of defining electrical fields (the other one is Maxwells equation defining a field as directly resulting from charges), we can not so easily do away with the energy contained in the field of a single charge. And if we look at this, the whole theory of electromagnetism blows up! If the charge is a point charge, we get infinite energy, and if it is not a point charge, we get other major contradictions.  
Not that it matters in everyday aspects  it is more like a philosophical aspect. If you want to know more about this, read chapter 28 in the "Feynman lectures, Vol. 2"  
But do not get confused now! The relation given above is perfectly valid for everyday circumstances and ordinary matter. Don't worry  be happy that a relatively complex issue has such a simple final formula! 
We now can relate the macroscopic and microscopic parameters. With the old relations and the new equation we have a grand total of:  


From this we obtain quite easily  


With N = density of dipoles  
Using the definition of P  


and inserting it into the equations above gives as final result the connection between the polarizability a ( the microscopic quantity) and the relative dielectric constant e_{r} (the macroscopic quantity):  

This is the Clausius  Mosotti equation, it relates the microscopic quantity a on the left hand side to the macroscopic quantity e_{r} (or, if you like that better, c = e_{r} – 1) on the right hand side of the equation. This has two far reaching consequences  
We now can calculate (at least in principle) the dielectric constants of all materials, because we know how to calculate a.  
We have an instrument to measure microscopic properties like the polarizability a, by measuring macroscopic properties like the dielectric constant and converting the numbers with the ClausiusMosotti equation.  
You must also see this in an historical context: With the ClausiusMosotti equation the dielectric properties of materials were essentially reduced to known electrical properties. There was nothing mysterious anymore about the relative dielectric constant. The next logical step now would be to apply quantum theory to dielectric properties.  
© H. Föll (Electronic Materials  Script)