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thermodynamics Thermodynamics is a branch of physics that deals with heat, work, and temperature, and their relation to energy, entropy, and the physical properties of matter and radiation. The behavior of these quantities is governed by the four laws of the ...
, the Onsager reciprocal relations express the equality of certain ratios between flows and
force In physics, a force is an influence that can change the motion of an object. A force can cause an object with mass to change its velocity (e.g. moving from a state of rest), i.e., to accelerate. Force can also be described intuitively as a p ...
s in
thermodynamic system A thermodynamic system is a body of matter and/or radiation, confined in space by walls, with defined permeabilities, which separate it from its surroundings. The surroundings may include other thermodynamic systems, or physical systems that are ...
s out of equilibrium, but where a notion of local equilibrium exists. "Reciprocal relations" occur between different pairs of forces and flows in a variety of physical systems. For example, consider fluid systems described in terms of temperature, matter density, and pressure. In this class of systems, it is known that
temperature Temperature is a physical quantity that expresses quantitatively the perceptions of hotness and coldness. Temperature is measured with a thermometer. Thermometers are calibrated in various temperature scales that historically have relied o ...
differences lead to
heat In thermodynamics, heat is defined as the form of energy crossing the boundary of a thermodynamic system by virtue of a temperature difference across the boundary. A thermodynamic system does not ''contain'' heat. Nevertheless, the term is al ...
flows from the warmer to the colder parts of the system; similarly,
pressure Pressure (symbol: ''p'' or ''P'') is the force applied perpendicular to the surface of an object per unit area over which that force is distributed. Gauge pressure (also spelled ''gage'' pressure)The preferred spelling varies by country and e ...
differences will lead to
matter In classical physics and general chemistry, matter is any substance that has mass and takes up space by having volume. All everyday objects that can be touched are ultimately composed of atoms, which are made up of interacting subatomic partic ...
flow from high-pressure to low-pressure regions. What is remarkable is the observation that, when both pressure and temperature vary, temperature differences at constant pressure can cause matter flow (as in
convection Convection is single or multiphase fluid flow that occurs spontaneously due to the combined effects of material property heterogeneity and body forces on a fluid, most commonly density and gravity (see buoyancy). When the cause of the convec ...
) and pressure differences at constant temperature can cause heat flow. Perhaps surprisingly, the heat flow per unit of pressure difference and the
density Density (volumetric mass density or specific mass) is the substance's mass per unit of volume. The symbol most often used for density is ''ρ'' (the lower case Greek letter rho), although the Latin letter ''D'' can also be used. Mathematical ...
(matter) flow per unit of temperature difference are equal. This equality was shown to be necessary by
Lars Onsager Lars Onsager (November 27, 1903 – October 5, 1976) was a Norwegian-born American physical chemist and theoretical physicist. He held the Gibbs Professorship of Theoretical Chemistry at Yale University. He was awarded the Nobel Prize in Che ...
using
statistical mechanics In physics, statistical mechanics is a mathematical framework that applies statistical methods and probability theory to large assemblies of microscopic entities. It does not assume or postulate any natural laws, but explains the macroscopic be ...
as a consequence of the
time reversibility A mathematical or physical process is time-reversible if the dynamics of the process remain well-defined when the sequence of time-states is reversed. A deterministic process is time-reversible if the time-reversed process satisfies the same dyn ...
of microscopic dynamics (
microscopic reversibility The principle of microscopic reversibility in physics and chemistry is twofold: * First, it states that the microscopic detailed dynamics of particles and fields is time-reversible because the microscopic equations of motion are symmetric with resp ...
). The theory developed by Onsager is much more general than this example and capable of treating more than two thermodynamic forces at once, with the limitation that "the principle of dynamical reversibility does not apply when (external) magnetic fields or Coriolis forces are present", in which case "the reciprocal relations break down". Though the fluid system is perhaps described most intuitively, the high precision of electrical measurements makes experimental realisations of Onsager's reciprocity easier in systems involving electrical phenomena. In fact, Onsager's 1931 paper refers to
thermoelectricity The thermoelectric effect is the direct conversion of temperature differences to electric voltage and vice versa via a thermocouple. A thermoelectric device creates a voltage when there is a different temperature on each side. Conversely, when ...
and transport phenomena in
electrolytes An electrolyte is a medium containing ions that is electrically conducting through the movement of those ions, but not conducting electrons. This includes most soluble salts, acids, and bases dissolved in a polar solvent, such as water. Upon di ...
as well known from the 19th century, including "quasi-thermodynamic" theories by
Thomson Thomson may refer to: Names * Thomson (surname), a list of people with this name and a description of its origin * Thomson baronets, four baronetcies created for persons with the surname Thomson Businesses and organizations * SGS-Thomson Mic ...
and
Helmholtz Hermann Ludwig Ferdinand von Helmholtz (31 August 1821 – 8 September 1894) was a German physicist and physician who made significant contributions in several scientific fields, particularly hydrodynamic stability. The Helmholtz Association, ...
respectively. Onsager's reciprocity in the thermoelectric effect manifests itself in the equality of the Peltier (heat flow caused by a voltage difference) and Seebeck (electric current caused by a temperature difference) coefficients of a thermoelectric material. Similarly, the so-called "direct
piezoelectric Piezoelectricity (, ) is the electric charge that accumulates in certain solid materials—such as crystals, certain ceramics, and biological matter such as bone, DNA, and various proteins—in response to applied Stress (mechanics), mechanical s ...
" (electric current produced by mechanical stress) and "reverse piezoelectric" (deformation produced by a voltage difference) coefficients are equal. For many kinetic systems, like the
Boltzmann equation The Boltzmann equation or Boltzmann transport equation (BTE) describes the statistical behaviour of a thermodynamic system not in a state of equilibrium, devised by Ludwig Boltzmann in 1872.Encyclopaedia of Physics (2nd Edition), R. G. Lerne ...
or
chemical kinetics Chemical kinetics, also known as reaction kinetics, is the branch of physical chemistry that is concerned with understanding the rates of chemical reactions. It is to be contrasted with chemical thermodynamics, which deals with the direction in wh ...
, the Onsager relations are closely connected to the principle of
detailed balance The principle of detailed balance can be used in kinetic systems which are decomposed into elementary processes (collisions, or steps, or elementary reactions). It states that at equilibrium, each elementary process is in equilibrium with its reve ...
and follow from them in the linear approximation near equilibrium.
Experiment An experiment is a procedure carried out to support or refute a hypothesis, or determine the efficacy or likelihood of something previously untried. Experiments provide insight into Causality, cause-and-effect by demonstrating what outcome oc ...
al verifications of the Onsager reciprocal relations were collected and analyzed by D. G. Miller for many classes of irreversible processes, namely for
thermoelectricity The thermoelectric effect is the direct conversion of temperature differences to electric voltage and vice versa via a thermocouple. A thermoelectric device creates a voltage when there is a different temperature on each side. Conversely, when ...
, electrokinetics, transference in
electrolytic An electrolyte is a medium containing ions that is electrically conducting through the movement of those ions, but not conducting electrons. This includes most soluble salts, acids, and bases dissolved in a polar solvent, such as water. Upon dis ...
solution Solution may refer to: * Solution (chemistry), a mixture where one substance is dissolved in another * Solution (equation), in mathematics ** Numerical solution, in numerical analysis, approximate solutions within specified error bounds * Soluti ...
s,
diffusion Diffusion is the net movement of anything (for example, atoms, ions, molecules, energy) generally from a region of higher concentration to a region of lower concentration. Diffusion is driven by a gradient in Gibbs free energy or chemical p ...
, conduction of heat and
electricity Electricity is the set of physical phenomena associated with the presence and motion of matter that has a property of electric charge. Electricity is related to magnetism, both being part of the phenomenon of electromagnetism, as described ...
in
anisotropic Anisotropy () is the property of a material which allows it to change or assume different properties in different directions, as opposed to isotropy. It can be defined as a difference, when measured along different axes, in a material's physic ...
solids Solid is one of the four fundamental states of matter (the others being liquid, gas, and plasma). The molecules in a solid are closely packed together and contain the least amount of kinetic energy. A solid is characterized by structural ri ...
, thermomagnetism and galvanomagnetism. In this classical review,
chemical reactions A chemical reaction is a process that leads to the chemical transformation of one set of chemical substances to another. Classically, chemical reactions encompass changes that only involve the positions of electrons in the forming and breaking ...
are considered as "cases with meager" and inconclusive evidence. Further theoretical analysis and experiments support the reciprocal relations for chemical kinetics with transport.
Kirchhoff's law of thermal radiation In heat transfer, Kirchhoff's law of thermal radiation refers to wavelength-specific radiative emission and absorption by a material body in thermodynamic equilibrium, including radiative exchange equilibrium. It is a special case of Onsage ...
is another special case of the Onsager reciprocal relations applied to the wavelength-specific radiative emission and
absorption Absorption may refer to: Chemistry and biology * Absorption (biology), digestion **Absorption (small intestine) *Absorption (chemistry), diffusion of particles of gas or liquid into liquid or solid materials *Absorption (skin), a route by which ...
by a material body in
thermodynamic equilibrium Thermodynamic equilibrium is an axiomatic concept of thermodynamics. It is an internal state of a single thermodynamic system, or a relation between several thermodynamic systems connected by more or less permeable or impermeable walls. In thermod ...
. For his discovery of these reciprocal relations,
Lars Onsager Lars Onsager (November 27, 1903 – October 5, 1976) was a Norwegian-born American physical chemist and theoretical physicist. He held the Gibbs Professorship of Theoretical Chemistry at Yale University. He was awarded the Nobel Prize in Che ...
was awarded the 1968
Nobel Prize in Chemistry ) , image = Nobel Prize.png , alt = A golden medallion with an embossed image of a bearded man facing left in profile. To the left of the man is the text "ALFR•" then "NOBEL", and on the right, the text (smaller) "NAT•" then "M ...
. The presentation speech referred to the three laws of thermodynamics and then added "It can be said that Onsager's reciprocal relations represent a further law making a thermodynamic study of irreversible processes possible." Some authors have even described Onsager's relations as the "Fourth law of thermodynamics".


Example: Fluid system


The fundamental equation

The basic thermodynamic potential is internal
energy In physics, energy (from Ancient Greek: ἐνέργεια, ''enérgeia'', “activity”) is the quantitative property that is transferred to a body or to a physical system, recognizable in the performance of work and in the form of heat a ...
. In a simple
fluid In physics, a fluid is a liquid, gas, or other material that continuously deforms (''flows'') under an applied shear stress, or external force. They have zero shear modulus, or, in simpler terms, are substances which cannot resist any shear ...
system, neglecting the effects of
viscosity The viscosity of a fluid is a measure of its resistance to deformation at a given rate. For liquids, it corresponds to the informal concept of "thickness": for example, syrup has a higher viscosity than water. Viscosity quantifies the inte ...
the fundamental thermodynamic equation is written: \mathrmU = T \, \mathrmS - P \, \mathrmV + \mu \, \mathrmM where ''U'' is the internal energy, ''T'' is temperature, ''S'' is entropy, ''P'' is the hydrostatic pressure, ''V'' is the volume, \mu is the chemical potential, and ''M'' mass. In terms of the internal energy density, ''u'', entropy density ''s'', and mass density \rho, the fundamental equation at fixed volume is written: \mathrmu = T \, \mathrms + \mu \, \mathrm\rho For non-fluid or more complex systems there will be a different collection of variables describing the work term, but the principle is the same. The above equation may be solved for the entropy density: \mathrms = \frac 1 T \, \mathrmu + \frac T \, \mathrm\rho The above expression of the first law in terms of entropy change defines the entropic
conjugate variables Conjugate variables are pairs of variables mathematically defined in such a way that they become Fourier transform duals, or more generally are related through Pontryagin duality. The duality relations lead naturally to an uncertainty relation— ...
of u and \rho, which are 1 / T and -\mu / T and are intensive quantities analogous to potential energies; their gradients are called thermodynamic forces as they cause flows of the corresponding extensive variables as expressed in the following equations.


The continuity equations

The conservation of mass is expressed locally by the fact that the flow of mass density \rho satisfies the
continuity equation A continuity equation or transport equation is an equation that describes the transport of some quantity. It is particularly simple and powerful when applied to a conserved quantity, but it can be generalized to apply to any extensive quantity. S ...
: \frac + \nabla \cdot \mathbf_\rho = 0, where \mathbf_\rho is the mass flux vector. The formulation of energy conservation is generally not in the form of a continuity equation because it includes contributions both from the macroscopic mechanical energy of the fluid flow and of the microscopic internal energy. However, if we assume that the macroscopic velocity of the fluid is negligible, we obtain energy conservation in the following form: \frac + \nabla \cdot \mathbf_u = 0, where u is the internal energy density and \mathbf_u is the internal energy flux. Since we are interested in a general imperfect fluid, entropy is locally not conserved and its local evolution can be given in the form of entropy density s as \frac + \nabla \cdot \mathbf_s = \frac where / is the rate of increase in entropy density due to the irreversible processes of equilibration occurring in the fluid and \mathbf_s is the entropy flux.


The phenomenological equations

In the absence of matter flows,
Fourier's law Conduction is the process by which heat is transferred from the hotter end to the colder end of an object. The ability of the object to conduct heat is known as its ''thermal conductivity'', and is denoted . Heat spontaneously flows along a tem ...
is usually written: \mathbf_ = -k\,\nabla T; where k is the
thermal conductivity The thermal conductivity of a material is a measure of its ability to conduct heat. It is commonly denoted by k, \lambda, or \kappa. Heat transfer occurs at a lower rate in materials of low thermal conductivity than in materials of high thermal ...
. However, this law is just a linear approximation, and holds only for the case where \nabla T \ll T, with the thermal conductivity possibly being a function of the thermodynamic state variables, but not their gradients or time rate of change. Assuming that this is the case, Fourier's law may just as well be written: \mathbf_u = k T^2 \nabla \frac 1 T; In the absence of heat flows,
Fick's law Fick's laws of diffusion describe diffusion and were derived by Adolf Fick in 1855. They can be used to solve for the diffusion coefficient, . Fick's first law can be used to derive his second law which in turn is identical to the diffusion eq ...
of diffusion is usually written: \mathbf_ = -D\,\nabla\rho, where ''D'' is the coefficient of diffusion. Since this is also a linear approximation and since the chemical potential is monotonically increasing with density at a fixed temperature, Fick's law may just as well be written: \mathbf_ = D'\,\nabla \frac T where, again, D' is a function of thermodynamic state parameters, but not their gradients or time rate of change. For the general case in which there are both mass and energy fluxes, the phenomenological equations may be written as: \mathbf_ = L_ \, \nabla \frac 1 T + L_ \, \nabla \frac T \mathbf_ = L_ \, \nabla \frac 1 T + L_ \, \nabla \frac T or, more concisely, \mathbf_\alpha = \sum_\beta L_\,\nabla f_\beta where the entropic "thermodynamic forces" conjugate to the "displacements" u and \rho are \nabla f_u = \nabla \frac 1 T and \nabla f_\rho = \nabla \frac T and L_ is the Onsager matrix of
transport coefficient A transport coefficient \gamma measures how rapidly a perturbed system returns to equilibrium. The transport coefficients occur in transport phenomenon with transport laws : \mathbf_k = \gamma_k \mathbf_k where: : \mathbf_k is a flux of the prop ...
s.


The rate of entropy production

From the fundamental equation, it follows that: \frac = \frac 1 T \frac + \frac T \frac and \mathbf_s = \frac 1 T \mathbf_u + \frac T \mathbf_\rho = \sum_\alpha \mathbf_\alpha f_\alpha Using the continuity equations, the rate of
entropy production Entropy production (or generation) is the amount of entropy which is produced in any irreversible processes such as heat and mass transfer processes including motion of bodies, heat exchange, fluid flow, substances expanding or mixing, anelastic d ...
may now be written: \frac = \mathbf_u \cdot \nabla \frac 1 T + \mathbf_\rho \cdot \nabla \frac T = \sum_\alpha \mathbf_\alpha \cdot \nabla f_\alpha and, incorporating the phenomenological equations: \frac = \sum_\alpha\sum_\beta L_(\nabla f_\alpha) \cdot (\nabla f_\beta) It can be seen that, since the entropy production must be non-negative, the Onsager matrix of phenomenological coefficients L_ is a
positive semi-definite matrix In mathematics, a symmetric matrix M with real entries is positive-definite if the real number z^\textsfMz is positive for every nonzero real column vector z, where z^\textsf is the transpose of More generally, a Hermitian matrix (that is, a co ...
.


The Onsager reciprocal relations

Onsager's contribution was to demonstrate that not only is L_ positive semi-definite, it is also symmetric, except in cases where time-reversal symmetry is broken. In other words, the cross-coefficients \ L_ and \ L_ are equal. The fact that they are at least proportional is suggested by simple
dimensional analysis In engineering and science, dimensional analysis is the analysis of the relationships between different physical quantities by identifying their base quantities (such as length, mass, time, and electric current) and units of measure (such as m ...
(i.e., both coefficients are measured in the same
unit Unit may refer to: Arts and entertainment * UNIT, a fictional military organization in the science fiction television series ''Doctor Who'' * Unit of action, a discrete piece of action (or beat) in a theatrical presentation Music * ''Unit'' (alb ...
s of temperature times mass density). The symmetry of the vector dot product (\nabla f_\alpha)\cdot(\nabla f_\beta) = (\nabla f_\beta)\cdot(\nabla f_\alpha) \,, in the last equation in the previous section, likewise suggests that L_ \, \overset \, L_ \,. The rate of entropy production for the above simple example uses only two entropic forces, and a 2×2 Onsager phenomenological matrix. The expression for the linear approximation to the fluxes and the rate of entropy production can very often be expressed in an analogous way for many more general and complicated systems.


Abstract formulation

Let x_1,x_2,\ldots,x_n denote fluctuations from equilibrium values in several thermodynamic quantities, and let S(x_1,x_2,\ldots,x_n) be the entropy. Then,
Boltzmann's entropy formula In statistical mechanics, Boltzmann's equation (also known as the Boltzmann–Planck equation) is a probability equation relating the entropy S, also written as S_\mathrm, of an ideal gas to the multiplicity (commonly denoted as \Omega or W), the ...
gives for the probability distribution function w =A\exp(S/k), where ''A'' is a constant, since the probability of a given set of fluctuations is proportional to the number of microstates with that fluctuation. Assuming the fluctuations are small, the probability distribution function can be expressed through the second differential of the entropy w = \tilde e^\, ; \quad \beta_ = \beta_= -\frac \frac\, , where we are using
Einstein summation convention In mathematics, especially the usage of linear algebra in Mathematical physics, Einstein notation (also known as the Einstein summation convention or Einstein summation notation) is a notational convention that implies summation over a set of i ...
and \beta_ is a positive definite symmetric matrix. Using the quasi-stationary equilibrium approximation, that is, assuming that the system is only slightly
non-equilibrium Non-equilibrium thermodynamics is a branch of thermodynamics that deals with physical systems that are not in thermodynamic equilibrium but can be described in terms of macroscopic quantities (non-equilibrium state variables) that represent an ext ...
, we have \dot_i = -\lambda_x_k Suppose we define ''thermodynamic conjugate'' quantities as X_i = -\frac\frac, which can also be expressed as linear functions (for small fluctuations): X_i= \beta_x_k Thus, we can write \dot_i=-\gamma_X_k where \gamma_=\lambda_\beta^_ are called ''kinetic coefficients'' The ''principle of symmetry of kinetic coefficients'' or the ''Onsager's principle'' states that \gamma is a symmetric matrix, that is \gamma_ = \gamma_


Proof

Define mean values \xi_i(t) and \Xi_i(t) of fluctuating quantities x_i and X_i respectively such that they take given values x_1,x_2,\ldots at t=0. Note that \dot_i(t) = -\gamma_\Xi_k(t). Symmetry of fluctuations under time reversal implies that \langle x_i(t) x_k(0)\rangle = \langle x_i(-t) x_k(0) \rangle = \langle x_i(0) x_k(t) \rangle. or, with \xi_i(t), we have \langle \xi_i(t) x_k \rangle=\langle x_i \xi_k(t) \rangle. Differentiating with respect to t and substituting, we get \gamma_ \langle\Xi_l(t)x_k\rangle = \gamma_ \langle x_i \Xi_l(t) \rangle. Putting t = 0 in the above equation, \gamma_ \langle X_l x_k\rangle = \gamma_ \langle X_l x_i \rangle. It can be easily shown from the definition that \langle X_ix_k\rangle=\delta_, and hence, we have the required result.


See also

*
Lars Onsager Lars Onsager (November 27, 1903 – October 5, 1976) was a Norwegian-born American physical chemist and theoretical physicist. He held the Gibbs Professorship of Theoretical Chemistry at Yale University. He was awarded the Nobel Prize in Che ...
* Langevin equation


References

{{DEFAULTSORT:Onsager Reciprocal Relations Equations of physics Laws of thermodynamics Non-equilibrium thermodynamics Thermodynamic equations