The Gibbs rotational ensemble represents the possible states of a mechanical system in thermal and rotational equilibrium at temperature and angular velocity .[1] The Jaynes procedure can be used to obtain this ensemble.[2] An ensemble is the set of microstates corresponding to a given macrostate.
The Gibbs rotational ensemble assigns a probability to a given microstate characterized by energy and angular momentum for a given temperature and rotational velocity .[1][3]
where is the partition function
Derivation
editThe Gibbs rotational ensemble can be derived using the same general method as to derive any ensemble, as given by E.T. Jaynes in his 1956 paper Information Theory and Statistical Mechanics.[3] Let be a function with expectation value
where is the probability of , which is not known a priori. The probabilities obey normalization
To find , the Shannon entropy is maximized, where the Shannon entropy goes as
The method of Lagrange multipliers is used to maximize under the constraints and the normalization condition, using Lagrange multipliers and to find
is found via normalization
and can be written as
where is the partition function
This is easily generalized to any number of equations via the incorporation of more Lagrange multipliers.[3]
Now investigating the Gibbs rotational ensemble, the method of Lagrange multipliers is again used to maximize the Shannon entropy , but this time under the constraints of energy expectation value and angular momentum expectation value ,[3] which gives as
Via normalization, is found to be
Like before, and are given by
The entropy of the system is given by
such that
where is the Boltzmann constant. The system is assumed to be in equilibrium, follow the laws of thermodynamics, and have fixed uniform temperature and angular velocity . The first law of thermodynamics as applied to this system is
Recalling the entropy differential
Combining the first law of thermodynamics with the entropy differential gives
Comparing this result with the entropy differential given by entropy maximization allows determination of and
which allows the probability of a given state to be written as
which is recognized as the probability of some microstate given a prescribed macrostate using the Gibbs rotational ensemble.[1][3][2] The term can be recognized as the effective Hamiltonian for the system, which then simplifies the Gibbs rotational partition function to that of a normal canonical system
Applicability
editThe Gibbs rotational ensemble is useful for calculations regarding rotating systems. It is commonly used for describing particle distribution in centrifuges. For example, take a rotating cylinder (height , radius ) with fixed particle number , fixed volume , fixed average energy , and average angular momentum . The expectation value of number density of particles at radius can be written as
Using the Gibbs rotational partition function, can be calculated to be
Density of a particle at a given point can be thought of as unity divided by an infinitesimal volume, which can be represented as a delta function.
which finally gives as
which is the expected result.
Difference between Grand canonical ensemble and Gibbs canonical ensemble
editThe Grand canonical ensemble and the Gibbs canonical ensemble are two different statistical ensembles used in statistical mechanics to describe systems with different constraints.
The grand canonical ensemble describes a system that can exchange both energy and particles with a reservoir. It is characterized by three variables: the temperature (T), chemical potential (μ), and volume (V) of the system.[4] The chemical potential determines the average particle number in this ensemble, which allows for some variation in the number of particles. The grand canonical ensemble is commonly used to study systems with a fixed temperature and chemical potential, but a variable particle number, such as gases in contact with a particle reservoir.[5]
On the other hand, the Gibbs canonical ensemble describes a system that can exchange energy but has a fixed number of particles. It is characterized by two variables: the temperature (T) and volume (V) of the system. In this ensemble, the energy of the system can fluctuate, but the number of particles remains fixed. The Gibbs canonical ensemble is commonly used to study systems with a fixed temperature and particle number, but variable energy, such as systems in thermal equilibrium.[6]
References
edit- ^ a b c Gibbs, Josiah Willard (2010) [1902]. Elementary Principles in Statistical Mechanics: Developed with Especial Reference to the Rational Foundation of Thermodynamics. Cambridge: Cambridge University Press. doi:10.1017/CBO9780511686948. ISBN 9781108017022.
- ^ a b Thomson, Mitchell; Dyer, Charles C. (2012-03-29). "Black Hole Statistical Mechanics and The Angular Velocity Ensemble". arXiv:1203.6542 [gr-qc].
- ^ a b c d e Jaynes, Edwin Thompson; Heims, S.P. (1962). "Theory of Gyromagnetic Effects and Some Related Magnetic Phenomena". Reviews of Modern Physics. 34 (2): 143–165. Bibcode:1962RvMP...34..143H. doi:10.1103/RevModPhys.34.143.
- ^ "Grand Canonical Ensemble - an overview | ScienceDirect Topics". www.sciencedirect.com. Retrieved 2023-05-15.
- ^ "LECTURE 9 Statistical Mechanics". ps.uci.edu. Retrieved 2023-05-15.
- ^ Emch, Gérard G.; Liu, Chuang (2002). "The Gibbs Canonical Ensembles". In Emch, Gérard G.; Liu, Chuang (eds.). The Logic of Thermostatistical Physics. Berlin, Heidelberg: Springer. pp. 331–372. doi:10.1007/978-3-662-04886-3_10. ISBN 978-3-662-04886-3. Retrieved 2023-05-15.