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123 class SpeciesThermoInterpType;
124 class VPStandardStateTP;
158 PDSS& operator=(
const PDSS& b) =
delete;
217 virtual doublereal
gibbs_RT()
const;
224 virtual doublereal
cp_mole()
const;
231 virtual doublereal
cp_R()
const;
238 virtual doublereal
cv_mole()
const;
252 virtual doublereal
density()
const;
315 virtual doublereal
cp_R_ref()
const;
328 virtual doublereal
pressure()
const;
366 virtual void setState_TP(doublereal temp, doublereal pres);
373 virtual void setState_TR(doublereal temp, doublereal rho);
456 virtual void reportParams(
size_t& kindex,
int& type, doublereal*
const c,
496 virtual doublereal
gibbs_RT()
const;
497 virtual doublereal
cp_R()
const;
509 virtual doublereal
cp_mole()
const;
519 virtual double cp_R()
const;
521 virtual double density()
const;
virtual doublereal gibbs_mole() const
Return the molar Gibbs free energy in units of J kmol-1.
doublereal m_minTemp
Minimum temperature.
virtual double enthalpy_RT_ref() const
Return the molar enthalpy divided by RT at reference pressure.
virtual double molarVolume_ref() const
Return the molar volume at reference pressure.
shared_ptr< SpeciesThermoInterpType > m_spthermo
Pointer to the species thermodynamic property manager.
virtual void setParametersFromXML(const XML_Node &speciesNode)
Initialization routine for the PDSS object based on the speciesNode.
virtual double gibbs_RT() const
Return the molar Gibbs free energy divided by RT.
virtual doublereal gibbsDelp_mole() const
Get the difference in the standard state Gibbs free energy between the current pressure and the refer...
virtual void setState_TR(doublereal temp, doublereal rho)
Set the internal temperature and density.
virtual doublereal entropy_R_ref() const
Return the molar entropy divided by R at reference pressure.
virtual doublereal cp_R_ref() const
Return the molar heat capacity divided by R at reference pressure.
void setMolecularWeight(doublereal mw)
Set the molecular weight of the species.
doublereal m_pres
State of the system - pressure.
virtual doublereal enthalpy_mole() const
Return the molar enthalpy in units of J kmol-1.
virtual doublereal cpDelp_mole() const
Get the difference in standard state heat capacity between the current pressure and the reference pre...
virtual doublereal cp_R() const
Return the molar const pressure heat capacity divided by RT.
doublereal m_p0
Reference state pressure of the species.
doublereal m_mw
Molecular Weight of the species.
virtual doublereal gibbs_mole() const
Return the molar Gibbs free energy in units of J kmol-1.
virtual doublereal cp_mole() const
Return the molar const pressure heat capacity in units of J kmol-1 K-1.
doublereal molecularWeight() const
Return the molecular weight of the species in units of kg kmol-1.
virtual doublereal entropy_R() const
Return the standard state entropy divided by RT.
double m_Vss
Standard State molar volume (m^3/kmol)
virtual doublereal molarVolume_ref() const
Return the molar volume at reference pressure.
virtual void setState_TP(doublereal temp, doublereal pres)
Set the internal temperature and pressure.
virtual void setParent(VPStandardStateTP *phase, size_t k)
Set the parent VPStandardStateTP object of this PDSS object.
virtual doublereal entropy_mole() const
Return the molar entropy in units of J kmol-1 K-1.
double m_sss_R
Standard state entropy divided by R.
virtual doublereal entropy_mole() const
Return the molar entropy in units of J kmol-1 K-1.
virtual void reportParams(size_t &kindex, int &type, doublereal *const c, doublereal &minTemp, doublereal &maxTemp, doublereal &refPressure) const
This utility function reports back the type of parameterization and all of the parameters for the spe...
virtual doublereal enthalpy_mole() const
Return the molar enthalpy in units of J kmol-1.
double m_V0
Reference state molar volume (m^3/kmol)
Base class for PDSS classes which compute nondimensional properties directly.
virtual doublereal thermalExpansionCoeff() const
Return the volumetric thermal expansion coefficient. Units: 1/K.
PDSS()
Default Constructor.
virtual double molarVolume() const
Return the molar volume at standard state.
virtual doublereal gibbs_RT_ref() const
Return the molar Gibbs free energy divided by RT at reference pressure.
virtual doublereal gibbs_RT() const
Return the molar Gibbs free energy divided by RT.
virtual double gibbs_RT_ref() const
Return the molar Gibbs free energy divided by RT at reference pressure.
virtual doublereal entropyDelp_mole() const
Get the difference in the standard state entropy between the current pressure and the reference press...
virtual double cp_R() const
Return the molar const pressure heat capacity divided by RT.
double m_gss_RT
Standard state Gibbs free energy divided by RT.
virtual doublereal molarVolume() const
Return the molar volume at standard state.
doublereal refPressure() const
Return the reference pressure for this phase.
virtual void setTemperature(doublereal temp)
Set the internal temperature.
virtual doublereal enthalpy_RT() const
Return the standard state molar enthalpy divided by RT.
Class XML_Node is a tree-based representation of the contents of an XML file.
double m_h0_RT
Reference state enthalpy divided by RT.
virtual double enthalpy_RT() const
Return the standard state molar enthalpy divided by RT.
void setParameters(const AnyMap &node)
Set model parameters from an AnyMap phase description, e.g.
virtual doublereal density() const
Return the standard state density at standard state.
virtual doublereal cp_R() const
Return the molar const pressure heat capacity divided by RT.
virtual doublereal critPressure() const
critical pressure
virtual doublereal pressure() const
Returns the pressure (Pa)
virtual doublereal satPressure(doublereal T)
saturation pressure
doublereal m_maxTemp
Maximum temperature.
virtual doublereal enthalpy_RT_ref() const
Return the molar enthalpy divided by RT at reference pressure.
double m_cpss_R
Standard state heat capacity divided by R.
doublereal maxTemp() const
return the minimum temperature
virtual doublereal gibbs_RT() const
Return the molar Gibbs free energy divided by RT.
virtual void initThermo()
Initialization routine.
double m_cp0_R
Reference state heat capacity divided by R.
virtual doublereal critTemperature() const
critical temperature
virtual doublereal enthalpyDelp_mole() const
Get the difference in the standard state enthalpy between the current pressure and the reference pres...
virtual void setPressure(doublereal pres)
Sets the pressure in the object.
virtual double entropy_R_ref() const
Return the molar entropy divided by R at reference pressure.
A map of string keys to values whose type can vary at runtime.
void setReferenceThermo(shared_ptr< SpeciesThermoInterpType > stit)
Set the SpeciesThermoInterpType object used to calculate reference state properties.
virtual doublereal cv_mole() const
Return the molar const volume heat capacity in units of J kmol-1 K-1.
AnyMap m_input
Input data supplied via setParameters.
virtual doublereal entropy_R() const
Return the standard state entropy divided by RT.
virtual doublereal temperature() const
Return the current stored temperature.
Base class for PDSS classes which compute molar properties directly.
double m_s0_R
Reference state entropy divided by R.
virtual double density() const
Return the standard state density at standard state.
virtual doublereal intEnergy_mole() const
Return the molar internal Energy in units of J kmol-1.
virtual double entropy_R() const
Return the standard state entropy divided by RT.
Virtual base class for a species with a pressure dependent standard state.
virtual doublereal cp_mole() const
Return the molar const pressure heat capacity in units of J kmol-1 K-1.
doublereal m_temp
Current temperature used by the PDSS object.
virtual doublereal critDensity() const
critical density
Namespace for the Cantera kernel.
double m_g0_RT
Reference state Gibbs free energy divided by RT.
doublereal minTemp() const
return the minimum temperature
double m_hss_RT
Standard state enthalpy divided by RT.
virtual doublereal enthalpy_RT() const
Return the standard state molar enthalpy divided by RT.
virtual double cp_R_ref() const
Return the molar heat capacity divided by R at reference pressure.