Cantera 2.6.0
Species Standard-State Thermodynamic Properties

In this module we describe Cantera's treatment of pressure dependent standard states (PDSS) objects. More...

Collaboration diagram for Species Standard-State Thermodynamic Properties:


class  PDSS
 Virtual base class for a species with a pressure dependent standard state. More...
class  PDSS_ConstVol
 Class for pressure dependent standard states that use a constant volume model. More...
class  PDSS_HKFT
 Class for pressure dependent standard states corresponding to ionic solutes in electrolyte water. More...
class  PDSS_IdealGas
 Derived class for pressure dependent standard states of an ideal gas species. More...
class  PDSS_IonsFromNeutral
 Derived class for pressure dependent standard states of an ideal gas species. More...
class  PDSS_SSVol
 Class for pressure dependent standard states that uses a standard state volume model of some sort. More...
class  PDSS_Water
 Class for the liquid water pressure dependent standard state. More...

Detailed Description

In this module we describe Cantera's treatment of pressure dependent standard states (PDSS) objects.

These are objects that calculate the standard state of a single species that depends on both temperature and pressure.

To compute the thermodynamic properties of multicomponent solutions, it is necessary to know something about the thermodynamic properties of the individual species present in the solution. Exactly what sort of species properties are required depends on the thermodynamic model for the solution. For a gaseous solution (that is, a gas mixture), the species properties required are usually ideal gas properties at the mixture temperature and at a reference pressure (almost always at 1 bar). For other types of solutions, however, it may not be possible to isolate the species in a "pure" state. For example, the thermodynamic properties of, say, Na+ and Cl- in saltwater are not easily determined from data on the properties of solid NaCl, or solid Na metal, or chlorine gas. In this case, the solvation in water is fundamental to the identity of the species, and some other reference state must be used. One common convention for liquid solutions is to use thermodynamic data for the solutes in the limit of infinite dilution within the pure solvent; another convention is to reference all properties to unit molality.

In defining these standard states for species in a phase, we make the following definition. A reference state is a standard state of a species in a phase limited to one particular pressure, the reference pressure. The reference state specifies the dependence of all thermodynamic functions as a function of the temperature, in between a minimum temperature and a maximum temperature. The reference state also specifies the molar volume of the species as a function of temperature. The molar volume is a thermodynamic function. A full standard state does the same thing as a reference state, but specifies the thermodynamics functions at all pressures.

Class PDSS is the base class for a family of classes that compute properties of a single species in a phase at its standard states, for a range of temperatures and pressures. PDSS objects are used by derivatives of the VPStandardState class. These classes assume that there exists a standard state for each species in the phase, where the thermodynamic functions are specified as a function of temperature and pressure. Standard state objects for each species in the phase are all derived from the PDSS virtual base class.

The following classes inherit from PDSS. Each of these classes handles just one species.

Normally the PDSS object is not called directly. Instead the VPStandardStateTP object manages the calls to the PDSS object for the entire set of species that comprise a phase.

The PDSS objects may or may not utilize a SpeciesThermoInterpType reference state manager class to calculate the reference state thermodynamics functions in their own calculation. There are some classes, such as PDSS_IdealGas and PDSS+_ConstVol, which utilize the SpeciesThermoInterpType object because the calculation is very similar to the reference state calculation, while there are other classes, PDSS_Water and PDSS_HKFT, which don't utilize the reference state calculation at all, because it wouldn't make sense to. For example, using the PDSS_Water module, there isn't anything special about the reference pressure of 1 bar, so the reference state calculation would represent a duplication of work. Additionally, when evaluating thermodynamic properties at higher pressures and temperatures, near the critical point, evaluation of the thermodynamics at a pressure of 1 bar may lead to situations where the liquid is unstable, that is, beyond the spinodal curve leading to potentially wrong evaluation results.