Partition function (statistical mechanics): Difference between revisions

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Revision as of 06:56, 23 April 2025 edit 202.92.134.21 (talk) →Classical continuous system ← Previous edit		Latest revision as of 08:22, 7 August 2025 edit undo 209.227.176.29 (talk) →Connection to probability theory
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Line 108: To make it into a dimensionless quantity, we must divide it by ''h'', which is some quantity with units of [[action (physics)\|action]] (usually taken to be the [[Planck constant]]). For generalized cases, the partition function of <math> N </math> particles in <math> d </math>-dimensions is given by <math display="block"> Z = \frac{1}{h^{Nd}} \int \prod_{i=1}^{N} e^{-\beta \mathcal{H}(~~q_i~~\textbf{q}_i, ~~p_i~~\textbf{p}_i)} \, d^d ~~q_i~~\textbf{q}_i \, d^d ~~p_i~~\textbf{p}_i, </math> ==== Classical continuous system (multiple identical particles) ==== Line 171: For simplicity, we will use the discrete form of the partition function in this section. Our results will apply equally well to the continuous form. Consider a system ''S'' embedded into a [[heat bath]] ''B''. Let the total [[energy]] of both systems be ''E''. Let ''p<sub>i</sub>'' denote the [[probability]] that the system ''S'' is in a particular [[Microstate (statistical mechanics)\|microstate]], ''i'', with energy ''E<sub>i</sub>''. According to the [[Statistical mechanics#Fundamental postulate\|fundamental postulate of statistical mechanics]] (which states that all attainable microstates of a system are equally probable), the probability ''p<sub>i</sub>'' will be ~~inversely~~ proportional to the number of microstates of the total [[Closed system (thermodynamics)\|closed system]] (''S'', ''B'') in which ''S'' is in microstate ''i'' with energy ''E<sub>i</sub>''. Equivalently, ''p<sub>i</sub>'' will be proportional to the number of microstates of the heat bath ''B'' with energy {{nowrap\|''E'' − ''E<sub>i</sub>''}}. We then normalize this by dividing by the total number of microstates in which the constraints we have imposed on the entire system; both S and the heat bath; hold. In this case the only constraint is that the total energy of both systems is ''E'', so: <math display="block">p_i = \frac{\Omega_B(E - E_i)}{\Omega_{(S,B)}(E)}.</math>