It was originally introduced in 1971 by, one of the proponents of the rational thermodynamicsschool of thought, based on earlier proposals for a "reciprocal temperature" function. Thermodynamic beta has units reciprocal to that of energy. In non-thermal units, it can also be measured in byte per joule, or more conveniently, gigabyte per nanojoule; 1 K−1 is equivalent to about 13,062 gigabytes per nanojoule; at room temperature: = 300K, β ≈ ≈ ≈.
Description
Thermodynamic beta is essentially the connection between the information theory and statistical mechanics interpretation of a physical system through its entropy and the thermodynamics associated with its energy. It expresses the response of entropy to an increase in energy. If a system is challenged with a small amount of energy, then β describes the amount the system will randomize. Via the statistical definition of temperature as a function of entropy, the coldness function can be calculated in the microcanonical ensemble from the formula .
From the statistical point of view, β is a numerical quantity relating two macroscopic systems in equilibrium. The exact formulation is as follows. Consider two systems, 1 and 2, in thermal contact, with respective energies E1 and E2. We assume E1 + E2 = some constantE. The number of microstates of each system will be denoted by Ω1 and Ω2. Under our assumptions Ωi depends only on Ei. Thus the number of microstates for the combined system is We will derive β from the fundamental assumption of statistical mechanics: Therefore, at equilibrium, But E1 + E2 = E implies So i.e. The above relation motivates a definition of β:
Connection of statistical view with thermodynamic view
When two systems are in equilibrium, they have the same thermodynamic temperature T. Thus intuitively, one would expectβ to be related to T in some way. This link is provided by Boltzmann's fundamental assumption written as where kB is the Boltzmann constant, S is the classicalthermodynamic entropy, and Ω is the number of microstates. So Substituting into the definition of β from the statistical definition above gives Comparing with thermodynamic formula we have where is called the fundamental temperature of the system, and has units of energy.
