Maxwell relationships description

This result, that the low frequency limit of the in phase component of the viscosity equates to the viscosity of the dashpot, means that for a single Maxwell model it is possible to replace rj by rj(0). Thus far we have concentrated on the description of experimental responses to the application of a strain. Similar constructions can be developed for the application of a stress. For example the application of an oscillating stress to a sample gives rise to an oscillating strain. We can define a complex compliance J which is the ratio of the strain to the stress. We will explore the relationship between different experiments and the resulting models in Section 4.6. 

Classical physics is based on the concept that things happen deterministically From A follows B andfrom B follows C and each of these successive outcomes can be described with some exact functional relationship. Such are Newtons s laws and Maxwell s equations, to mention just two examples. Of course, scientists like Newton, Maxwell, and others were well aware of the seemingly irregular, unpredictable (random) nature of certain phenomena. The movement of the smoke from a chimney and the flow of the water in a river look rather irregular. Yet, these scientists were convinced that if only we were able to break down the description of the system to the smallest possible level (e.g., the molecules), the motion would turn out to be deterministic again. 

The kinetic molecular theory (KMT see Sidebar 2.7) of Bernoulli, Maxwell, and others provides deep insight into the molecular origin of thermodynamic gas properties. From the KMT viewpoint, pressure P arises merely from the innumerable molecular collisions with the walls of a container, whereas temperature T is proportional to the average kinetic energy of random molecular motions in the container of volume V. KMT starts from an ultrasimplified picture of each molecule as a mathematical point particle (i.e., with no volume ) with mass m and average velocity v, but no potential energy of interaction with other particles. From this purely kinetic picture of chaotic molecular motions and wall collisions, one deduces that the PVT relationships must be those of an ideal gas, (2.2). Hence, the inaccuracies of the ideal gas approximation can be attributed to the unrealistically oversimplified noninteracting point mass picture of molecules that underlies the KMT description. 

Dayhoff [50] suggested that one might measure a rest mass of photon by designing a low-frequency oscillator from an inductor-capacitor (LC) network. The expected frequency can be calculated from Maxwell s equations, and this may be used to give an effective wavelength for photons of that frequency. He claimed that one would have a measure of the dispersion relationship at low frequencies. Williams [51] calculated the effective capacitance of a spherical capacitor using Proca equations. This calculation can then be generalized to any capacitor with the result that a capacitor has an additional term that is quadratic in the area of the plates of the capacitor. However, this term is not exactly the one that Dayhoff referred to. But it seems to be a very close description of it. One can add two identical capacitors C in parallel and obtain the result... 

The Kramers-Kronig are integral equations that constrain the real and imaginary components of complex quantities for systems that satisfy conditions of linearity, causality, and stability. These relationships, derived independently by Kronig and Kramers, were initially developed from the constitutive relations associated with the Maxwell equations for description of an electromagnetic field at interior points in matter. 

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