Just as a small increment of energy in a mechanical system is the product of a force times a small displacement, so an increment in the energy of a thermodynamic system can be expressed as the sum of the products of certain generalized "forces" which, when unbalanced, cause certain generalized "displacements" to occur, with their product being the energy transferred as a result. These forces and their associated displacements are called
conjugate variables. For example, consider the pV conjugate pair. The pressure p acts as a generalized force: Pressure differences force a change in volume \mathrm dV, and their product is the energy lost by the system due to work. Here, pressure is the driving force, volume is the associated displacement, and the two form a pair of conjugate variables. In a similar way, temperature differences drive changes in entropy, and their product is the energy transferred by heat transfer. The thermodynamic force is always an
intensive variable and the displacement is always an
extensive variable, yielding an extensive energy. The intensive (force) variable is the derivative of the (extensive) internal energy with respect to the extensive (displacement) variable, with all other extensive variables held constant. The theory of thermodynamic potentials is not complete until one considers the number of particles in a system as a variable on par with the other extensive quantities such as volume and entropy. The number of particles is, like volume and entropy, the displacement variable in a conjugate pair. The generalized force component of this pair is the
chemical potential. The chemical potential may be thought of as a force which, when imbalanced, pushes an exchange of particles, either with the surroundings, or between phases inside the system. In cases where there are a mixture of chemicals and phases, this is a useful concept. For example, if a container holds liquid water and water vapor, there will be a chemical potential (which is negative) for the liquid which pushes the water molecules into the vapor (evaporation) and a chemical potential for the vapor, pushing vapor molecules into the liquid (condensation). Only when these "forces" equilibrate, and the chemical potential of each phase is equal, is equilibrium obtained. The most commonly considered conjugate thermodynamic variables are (with corresponding
SI units): :Thermal parameters: :*
Temperature: T (
K) :*
Entropy: S (J K−1) :Mechanical parameters: :*
Pressure: p (
Pa= J m−3) :*
Volume: V (m3 = J Pa−1) ::or, more generally, :*
Stress: \sigma_{ij}\, (
Pa= J m−3) :* Volume ×
Strain: V\times\varepsilon_{ij} (m3 = J Pa−1) :Material parameters: :*
chemical potential: \mu (J) :*
particle number: N (particles or mole) For a system with different types i of particles, a small change in the internal energy is given by: :\mathrm{d}U = T\,\mathrm{d}S - p\,\mathrm{d}V + \sum_i \mu_i \,\mathrm{d}N_i\,, where U is internal energy, T is temperature, S is entropy, p is pressure, V is volume, \mu_i is the chemical potential of the i-th particle type, and N_i is the number of i-type particles in the system. Here, the temperature, pressure, and chemical potential are the generalized forces, which drive the generalized changes in entropy, volume, and particle number respectively. These parameters all affect the
internal energy of a thermodynamic system. A small change \mathrm{d}U in the internal energy of the system is given by the sum of the flow of energy across the boundaries of the system due to the corresponding conjugate pair. These concepts will be expanded upon in the following sections. While dealing with processes in which systems exchange matter or energy, classical thermodynamics is not concerned with the
rate at which such processes take place, termed
kinetics. For this reason, the term
thermodynamics is usually used synonymously with
equilibrium thermodynamics. A central notion for this connection is that of
quasistatic processes, namely idealized, "infinitely slow" processes. Time-dependent thermodynamic processes far away from equilibrium are studied by
non-equilibrium thermodynamics. This can be done through linear or non-linear analysis of
irreversible processes, allowing systems near and far away from equilibrium to be studied, respectively. == Pressure/volume and stress/strain pairs ==