Octamethyltrisiloxane Class

State equations and constants of octamethyltrisiloxane. Short name: MDM. Synomym: MDM. Chemical formula: C8H24O2Si3.

Inheritance Hierarchy

SystemObject
  Altaxo.Science.Thermodynamics.FluidsHelmholtzEquationOfState
    Altaxo.Science.Thermodynamics.FluidsHelmholtzEquationOfStateOfPureFluids
      Altaxo.Science.Thermodynamics.FluidsHelmholtzEquationOfStateOfPureFluidsBySpanEtAl
        Altaxo.Science.Thermodynamics.FluidsOctamethyltrisiloxane

Namespace: Altaxo.Science.Thermodynamics.Fluids
Assembly: AltaxoCore (in AltaxoCore.dll) Version: 4.8.3572.0 (4.8.3572.0)

Syntax

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public class Octamethyltrisiloxane : HelmholtzEquationOfStateOfPureFluidsBySpanEtAl

The Octamethyltrisiloxane type exposes the following members.

Properties

	Name	Description
	AcentricFactor	Gets the acentric factor. (Overrides HelmholtzEquationOfStateOfPureFluidsAcentricFactor)
	CASRegistryNumber	Gets the CAS registry number. (Overrides HelmholtzEquationOfStateOfPureFluidsBySpanEtAlCASRegistryNumber)
	ChemicalFormula	The chemical formula of the fluid. (Overrides HelmholtzEquationOfStateOfPureFluidsBySpanEtAlChemicalFormula)
	CriticalPointMassDensity	Gets the mass density at the critical point in kg/m³. (Inherited from HelmholtzEquationOfStateOfPureFluids)
	CriticalPointMoleDensity	Gets the mole density at the critical point in mol/m³. (Overrides HelmholtzEquationOfStateOfPureFluidsCriticalPointMoleDensity)
	CriticalPointPressure	Gets the pressure at the critical point in Pa. (Overrides HelmholtzEquationOfStateOfPureFluidsCriticalPointPressure)
	CriticalPointTemperature	Gets the temperature at the critical point in K. (Overrides HelmholtzEquationOfStateOfPureFluidsCriticalPointTemperature)
	DipoleMoment	Gets the dipole moment in Debye. (Overrides HelmholtzEquationOfStateOfPureFluidsBySpanEtAlDipoleMoment)
	FluidFamily	The chemical formula of the fluid. (Overrides HelmholtzEquationOfStateOfPureFluidsBySpanEtAlFluidFamily)
	FullName	The full name of the fluid. (Overrides HelmholtzEquationOfStateOfPureFluidsBySpanEtAlFullName)
	Instance	Gets the (only) instance of this class.
	IsMeltingPressureCurveImplemented	Gets a value indicating whether a melting-pressure curve is implemented for this fluid. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	IsSublimationPressureCurveImplemented	Gets a value indicating whether a sublimation-pressure curve is implemented for this fluid. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	LowerTemperatureLimit	Gets the lower temperature limit of this model in K. (Overrides HelmholtzEquationOfStateOfPureFluidsBySpanEtAlLowerTemperatureLimit)
	MolecularWeight	Gets the molecular weight in kg/mol. (Overrides HelmholtzEquationOfStateMolecularWeight)
	MolecularWeightWithDimension	Gets the (typical) molecular weight of the fluid. (Inherited from HelmholtzEquationOfState)
	NormalBoilingPointTemperature	Gets the boiling temperature at normal pressure (101325 Pa) in K (if existent). If not existent, the return value is null. (Overrides HelmholtzEquationOfStateOfPureFluidsNormalBoilingPointTemperature)
	NormalSublimationPointTemperature	Gets the sublimation temperature at normal pressure (101325 Pa) in K (if existent). If not existent, the return value is null. (Overrides HelmholtzEquationOfStateOfPureFluidsNormalSublimationPointTemperature)
	ReducingMassDensity	Gets the density (in kg/m³) used to calculate the reduced (dimensionless) density. (Inherited from HelmholtzEquationOfState)
	ReducingMassDensityWithDimension	Gets the density (in kg/m³) used to calculate the reduced (dimensionless) density. (Inherited from HelmholtzEquationOfState)
	ReducingMoleDensity	Gets the molar density (in mol/m³) used to calculate the reduced (dimensionless) density. (Inherited from HelmholtzEquationOfStateOfPureFluids)
	ReducingMoleDensityWithDimension	Gets the molar density (in mol/m³) used to calculate the reduced (dimensionless) density. (Inherited from HelmholtzEquationOfState)
	ReducingTemperature	Gets the temperature (in Kelvin) that is used to calculate the inverse reduced temperature. (Inherited from HelmholtzEquationOfStateOfPureFluids)
	ReducingTemperatureWithDimension	Gets the temperature (in Kelvin) that is used to calculate the inverse reduced temperature. (Inherited from HelmholtzEquationOfState)
	ShortName	The short name of the fluid. (Overrides HelmholtzEquationOfStateOfPureFluidsBySpanEtAlShortName)
	Synonym	The synonym of the name of the fluid. (Overrides HelmholtzEquationOfStateOfPureFluidsBySpanEtAlSynonym)
	TriplePointPressure	Gets the triple point pressure in Pa. (Overrides HelmholtzEquationOfStateOfPureFluidsTriplePointPressure)
	TriplePointSaturatedLiquidMassDensity	Gets the saturated liquid density at the triple point in kg/m³. (Inherited from HelmholtzEquationOfStateOfPureFluids)
	TriplePointSaturatedLiquidMoleDensity	Gets the triple point liquid mole density in mol/m³. (Overrides HelmholtzEquationOfStateOfPureFluidsTriplePointSaturatedLiquidMoleDensity)
	TriplePointSaturatedVaporMassDensity	Gets the saturated vapor density at the triple point in kg/m³. (Inherited from HelmholtzEquationOfStateOfPureFluids)
	TriplePointSaturatedVaporMoleDensity	Gets the triple point vapor mole density in mol/m³. (Overrides HelmholtzEquationOfStateOfPureFluidsTriplePointSaturatedVaporMoleDensity)
	TriplePointTemperature	Gets the triple point temperature in K. (Overrides HelmholtzEquationOfStateOfPureFluidsTriplePointTemperature)
	UN_Numbers	The UN number of the fluid. (Overrides HelmholtzEquationOfStateOfPureFluidsBySpanEtAlUN_Numbers)
	UpperMoleDensityLimit	Gets the upper density limit of this model in mol/m³. (Overrides HelmholtzEquationOfStateOfPureFluidsBySpanEtAlUpperMoleDensityLimit)
	UpperPressureLimit	Gets the upper pressure limit of this model in Pa. (Overrides HelmholtzEquationOfStateOfPureFluidsBySpanEtAlUpperPressureLimit)
	UpperTemperatureLimit	Gets the upper temperature limit of this model in K. (Overrides HelmholtzEquationOfStateOfPureFluidsBySpanEtAlUpperTemperatureLimit)
	WorkingSpecificGasConstant	Gets the specific gas constant of the fluid. Is calculated from WorkingUniversalGasConstant and MolecularWeight. (Inherited from HelmholtzEquationOfState)
	WorkingSpecificGasConstantWithDimension	Gets the specific gas constant of the fluid. Is calculated from WorkingUniversalGasConstant and MolecularWeight. (Inherited from HelmholtzEquationOfState)
	WorkingUniversalGasConstant	The Universal Gas Constant R at the time the model was developed. (Overrides HelmholtzEquationOfStateOfPureFluidsBySpanEtAlWorkingUniversalGasConstant)
	WorkingUniversalGasConstantWithDimension	Gets the universal gas constant that was used at the time this model was developed. (Inherited from HelmholtzEquationOfState)

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Methods

	Name	Description
	CoefficientOfFugacity_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the dimensionless coefficient of fugacity from mass density and temperature. (Inherited from HelmholtzEquationOfState)
	CoefficientOfFugacity_FromMassDensityAndTemperature(Double, Double)	Gets the dimensionless coefficient of fugacity from mole density and temperature. (Inherited from HelmholtzEquationOfState)
	CoefficientOfFugacity_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the dimensionless coefficient of fugacity from mole density and temperature. (Inherited from HelmholtzEquationOfState)
	CoefficientOfFugacity_FromMoleDensityAndTemperature(Double, Double)	Gets the dimensionless coefficient of fugacity from mole density and temperature. (Inherited from HelmholtzEquationOfState)
	Equals	Determines whether the specified object is equal to the current object. (Inherited from Object)
	Finalize	Allows an object to try to free resources and perform other cleanup operations before it is reclaimed by garbage collection. (Inherited from Object)
	GetDeltaFromMassDensity	Gets the reduced density by density / ReducingMassDensity. (Inherited from HelmholtzEquationOfState)
	GetDeltaFromMoleDensity	Gets the reduced density by density / ReducingMassDensity. (Inherited from HelmholtzEquationOfState)
	GetHashCode	Serves as the default hash function. (Inherited from Object)
	GetTauFromTemperature	Gets the inverse reduced temperature by ReducingTemperature / temperature. (Inherited from HelmholtzEquationOfState)
	GetTemperatureAfterAdiabaticPressureChangeInGasPhase(DimensionfulQuantity, DimensionfulQuantity, DimensionfulQuantity)	Gets the gas temperature after an adiabatic pressure change in a gas. ATTENTION UNCHECKED: this function assumes that the adiabatic pressure change happens in single gas phase, i.e., no phase transitions occur. (Inherited from HelmholtzEquationOfState)
	GetTemperatureAfterAdiabaticPressureChangeInGasPhase(Double, Double, Double)	Gets the gas temperature after an adiabatic pressure change in a gas. ATTENTION UNCHECKED: this function assumes that the adiabatic pressure change happens in single gas phase, i.e., no phase transitions occur. (Inherited from HelmholtzEquationOfState)
	GetTemperatureAfterIsenthalpicPressureChangeInGasPhase(DimensionfulQuantity, DimensionfulQuantity, DimensionfulQuantity)	Gets the gas temperature after an isenthalpic pressure change in a gas. For example, this is the case if the gas is expanded through a throttle valve. ATTENTION UNCHECKED: this function assumes that the adiabatic pressure change happens in single gas phase, i.e., no phase transitions occur. (Inherited from HelmholtzEquationOfState)
	GetTemperatureAfterIsenthalpicPressureChangeInGasPhase(Double, Double, Double)	Gets the gas temperature after an isenthalpic pressure change in a gas. For example, this is the case if the gas is expanded through a throttle valve. ATTENTION UNCHECKED: this function assumes that the isenthalpic pressure change happens in single gas phase, i.e., no phase transitions occur. (Inherited from HelmholtzEquationOfState)
	GetType	Gets the Type of the current instance. (Inherited from Object)
	IsentropicDerivativeOfMassSpecificVolumeWrtPressure_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the isentropic (adiabatic) derivative of the mass specific volume w.r.t. pressure from mole density and temperature. (Inherited from HelmholtzEquationOfState)
	IsentropicDerivativeOfMassSpecificVolumeWrtPressure_FromMoleDensityAndTemperature(Double, Double)	Gets the isentropic (adiabatic) derivative of the mass specific volume w.r.t. pressure from mole density and temperature. (Inherited from HelmholtzEquationOfState)
	IsentropicDerivativeOfMoleSpecificVolumeWrtPressure_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the isentropic (adiabatic) derivative of the mole specific volume w.r.t. pressure from mole density and temperature. (Inherited from HelmholtzEquationOfState)
	IsentropicDerivativeOfMoleSpecificVolumeWrtPressure_FromMoleDensityAndTemperature(Double, Double)	Gets the isentropic (adiabatic) derivative of the mole specific volume w.r.t. pressure from mole density and temperature. (Inherited from HelmholtzEquationOfState)
	IsothermalCompressibility_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the isothermal compressibility in 1/Pa from mass density (kg/m³) and temperature (K). Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	IsothermalCompressibility_FromMassDensityAndTemperature(Double, Double)	Gets the isothermal compressibility in 1/Pa from mass density (kg/m³) and temperature (K). Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	IsothermalCompressibility_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the isothermal compressibility in 1/Pa from mole density (mol/m³) and temperature (K). Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	IsothermalCompressibility_FromMoleDensityAndTemperature(Double, Double)	Gets the isothermal compressibility in 1/Pa from mole density (mol/m³) and temperature (K). Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	IsothermalCompressionalModulus_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the isothermal compressional modulus K in Pa from density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	IsothermalCompressionalModulus_FromMassDensityAndTemperature(Double, Double)	Gets the isothermal compressional modulus K in Pa from density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	IsothermalCompressionalModulus_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the isothermal compressional modulus in Pa from density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	IsothermalCompressionalModulus_FromMoleDensityAndTemperature(Double, Double)	Gets the isothermal compressional modulus in Pa from density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	IsothermalDerivativePressureWrtMassDensity_FromMassDensityAndTemperature	Gets the derivative of pressure w.r.t. the mass density at isothermal conditions. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	IsothermalDerivativePressureWrtMoleDensity_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the derivative of pressure w.r.t. the mole density at isothermal conditions. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	IsothermalDerivativePressureWrtMoleDensity_FromMoleDensityAndTemperature(Double, Double)	Gets the derivative of pressure w.r.t. the mole density at isothermal conditions. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	JouleThomsonCoefficient_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the Joule-Thomson coefficient from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	JouleThomsonCoefficient_FromMassDensityAndTemperature(Double, Double)	Get the Joule-Thomson coefficient from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	JouleThomsonCoefficient_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the Joule-Thomson coefficient from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	JouleThomsonCoefficient_FromMoleDensityAndTemperature(Double, Double)	Get the Joule-Thomson coefficient from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassDensity_FromMoleDensity(DimensionfulQuantity)	Gets the mass density (SIUnit: kg/m³) from mole density (SIUnit: mol/m³). (Inherited from HelmholtzEquationOfState)
	MassDensity_FromMoleDensity(Double)	Gets the mass density (in kg/m³) from mole density (in mol/m³). (Inherited from HelmholtzEquationOfState)
	MassDensity_FromPressureAndTemperature(DimensionfulQuantity, DimensionfulQuantity, Double)	Gets the mass density for a given pressure and temperature. (Inherited from HelmholtzEquationOfState)
	MassDensity_FromPressureAndTemperature(Double, Double, Double)	Gets the mass density for a given pressure and temperature. (Inherited from HelmholtzEquationOfState)
	MassDensity_FromPressureAndTemperature(DimensionfulQuantity, DimensionfulQuantity, Double, DimensionfulQuantity)	Gets the mass density from a given pressure and temperature. (Inherited from HelmholtzEquationOfState)
	MassDensity_FromPressureAndTemperature(Double, Double, Double, Double)	Gets the mass density from a given pressure and temperature. (Inherited from HelmholtzEquationOfState)
	MassSpecificEnthalpy_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the enthalpy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificEnthalpy_FromMassDensityAndTemperature(Double, Double)	Get the enthalpy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificEnthalpy_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the enthalpy from a given density and temperature. (Inherited from HelmholtzEquationOfState)
	MassSpecificEnthalpy_FromMoleDensityAndTemperature(Double, Double)	Get the enthalpy from a given density and temperature. (Inherited from HelmholtzEquationOfState)
	MassSpecificEntropy_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the entropy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificEntropy_FromMassDensityAndTemperature(Double, Double)	Get the entropy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificEntropy_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the entropy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificEntropy_FromMoleDensityAndTemperature(Double, Double)	Get the entropy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificGibbsEnergy_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the mass specific Gibbs energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificGibbsEnergy_FromMassDensityAndTemperature(Double, Double)	Get the mass specific Gibbs energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificGibbsEnergy_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the mass specific Gibbs energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificGibbsEnergy_FromMoleDensityAndTemperature(Double, Double)	Get the mass specific Gibbs energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificHelmholtzEnergy_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the Helmholtz energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificHelmholtzEnergy_FromMassDensityAndTemperature(Double, Double)	Get the Helmholtz energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificHelmholtzEnergy_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the mass specific Helmholtz energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificHelmholtzEnergy_FromMoleDensityAndTemperature(Double, Double)	Get the mass specific Helmholtz energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificInternalEnergy_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the internal energy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificInternalEnergy_FromMassDensityAndTemperature(Double, Double)	Get the internal energy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificInternalEnergy_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the internal energy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificInternalEnergy_FromMoleDensityAndTemperature(Double, Double)	Get the internal energy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificIsobaricHeatCapacity_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the isobaric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificIsobaricHeatCapacity_FromMassDensityAndTemperature(Double, Double)	Gets the isobaric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificIsobaricHeatCapacity_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the isobaric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificIsobaricHeatCapacity_FromMoleDensityAndTemperature(Double, Double)	Gets the isobaric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificIsochoricHeatCapacity_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the isochoric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificIsochoricHeatCapacity_FromMassDensityAndTemperature(Double, Double)	Get the isochoric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificIsochoricHeatCapacity_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the isochoric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MassSpecificIsochoricHeatCapacity_FromMoleDensityAndTemperature(Double, Double)	Get the isochoric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MeltingPressure_Type1	Evaluates the melting-pressure equation of type 1. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	MeltingPressure_Type2	Evaluates the melting-pressure equation of type 2. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	MeltingPressure_TypeH(Double)	Melting pressure for water. Note that more than one pressure value is possible for a given temperature. If in doubt, the lowest pressure solution is returned. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	MeltingPressure_TypeH(Double, Int32)	Melting pressure for a specific water equation segment. Calculates the melting pressure and its temperature derivative using the coefficient set for the selected triple-point segment. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	MeltingPressureEstimate_FromTemperature	Gets an estimate of the melting pressure for the specified temperature. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	MeltingPressureEstimateAndDerivativeWrtTemperature_FromTemperature	Gets an estimate value of the melting pressure and the derivative of the pressure w.r.t. temperature for a given temperature. The estimated value should have an relative accuracy of 5% plus an absolute error of about 100 Pa. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	MeltingTemperatureEstimate_FromPressure	Gets an estimate of the melting temperature for a given pressure, using Newton-Raphson iteration. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	MemberwiseClone	Creates a shallow copy of the current Object. (Inherited from Object)
	MoleDensity_FromMassDensity(DimensionfulQuantity)	Gets the mole density from mass density. (Inherited from HelmholtzEquationOfState)
	MoleDensity_FromMassDensity(Double)	Gets the mole density (in mol/m³) from mass density (in kg/m³). (Inherited from HelmholtzEquationOfState)
	MoleDensity_FromPressureAndTemperature(DimensionfulQuantity, DimensionfulQuantity, Double)	Get the mole density for a given pressure and temperature. (Inherited from HelmholtzEquationOfState)
	MoleDensity_FromPressureAndTemperature(Double, Double, Double)	Get the mole density for a given pressure and temperature. (Inherited from HelmholtzEquationOfState)
	MoleDensity_FromPressureAndTemperature(DimensionfulQuantity, DimensionfulQuantity, Double, DimensionfulQuantity)	Gets the mole density from a given pressure and temperature. (Inherited from HelmholtzEquationOfState)
	MoleDensity_FromPressureAndTemperature(Double, Double, Double, Double)	Gets the mole density from a given pressure and temperature. (Inherited from HelmholtzEquationOfState)
	MoleDensityEstimates_FromPressureAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets an estimate of the mole densities at a given pressure and temperature. (Inherited from HelmholtzEquationOfState)
	MoleDensityEstimates_FromPressureAndTemperature(Double, Double)	Gets an estimate of the mole densities at a given pressure and temperature. (Inherited from HelmholtzEquationOfStateOfPureFluids)
	MoleSpecificEnthalpy_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the enthalpy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificEnthalpy_FromMassDensityAndTemperature(Double, Double)	Get the enthalpy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificEnthalpy_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the enthalpy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificEnthalpy_FromMoleDensityAndTemperature(Double, Double)	Get the enthalpy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificEntropy_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the entropy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificEntropy_FromMassDensityAndTemperature(Double, Double)	Get the entropy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificEntropy_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the entropy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificEntropy_FromMoleDensityAndTemperature(Double, Double)	Get the entropy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificGibbsEnergy_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the mole specific Gibbs energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificGibbsEnergy_FromMassDensityAndTemperature(Double, Double)	Get the mole specific Gibbs energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificGibbsEnergy_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the mole specific Gibbs energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificGibbsEnergy_FromMoleDensityAndTemperature(Double, Double)	Get the mole specific Gibbs energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificHelmholtzEnergy_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the Helmholtz energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificHelmholtzEnergy_FromMassDensityAndTemperature(Double, Double)	Get the Helmholtz energy from a given mass density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificHelmholtzEnergy_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the Helmholtz energy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificHelmholtzEnergy_FromMoleDensityAndTemperature(Double, Double)	Get the Helmholtz energy from a given mole density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificInternalEnergy_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the internal energy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificInternalEnergy_FromMassDensityAndTemperature(Double, Double)	Get the internal energy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificInternalEnergy_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the internal energy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificInternalEnergy_FromMoleDensityAndTemperature(Double, Double)	Get the internal energy from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificIsobaricHeatCapacity_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the isobaric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificIsobaricHeatCapacity_FromMassDensityAndTemperature(Double, Double)	Gets the isobaric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificIsobaricHeatCapacity_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the isobaric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificIsobaricHeatCapacity_FromMoleDensityAndTemperature(Double, Double)	Gets the isobaric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificIsochoricHeatCapacity_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the mole specific isochoric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificIsochoricHeatCapacity_FromMassDensityAndTemperature(Double, Double)	Get the mole specific isochoric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificIsochoricHeatCapacity_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the mole specific isochoric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	MoleSpecificIsochoricHeatCapacity_FromMoleDensityAndTemperature(Double, Double)	Get the mole specific isochoric heat capacity from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	Phi0_OfReducedVariables	Calculates the ideal (zero-density) part of the dimensionless Helmholtz free energy for the supplied reduced variables. See Page 1541, Table 28 in [2]. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	Phi0_tau_OfReducedVariables	First derivative of Phi0 the of reduced variables with respect to the inverse reduced temperature. (Page 1541, Table 28) (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	Phi0_tautau_OfReducedVariables	Second derivative of Phi0 the of reduced variables with respect to the inverse reduced temperature. (Page 1541, Table 28) (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	PhiR_delta_OfReducedVariables	Calculates the first derivative of the residual part of the dimensionless Helmholtz energy with respect to the reduced density delta. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	PhiR_deltadelta_OfReducedVariables	Calculates the second derivative of the residual part of the dimensionless Helmholtz energy with respect to the reduced density delta. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	PhiR_deltatau_OfReducedVariables	Calculates the derivative of the residual part of the dimensionless Helmholtz energy with respect to the reduced density delta and the inverse reduced temperature tau. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	PhiR_OfReducedVariables	Calculates the residual part of the dimensionless Helmholtz energy in dependence on reduced density and reduced inverse temperature. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	PhiR_tau_OfReducedVariables	Calculates the first derivative of the residual part of the dimensionless Helmholtz energy with respect to the inverse reduced temperature. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	PhiR_tautau_OfReducedVariables	Calculates the second derivative of the residual part of the dimensionless Helmholtz energy with respect to the inverse reduced temperature. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	Pressure_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the pressure from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	Pressure_FromMassDensityAndTemperature(Double, Double)	Get the pressure from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	Pressure_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Gets the pressure from a given molar density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	Pressure_FromMoleDensityAndTemperature(Double, Double)	Gets the pressure from a given molar density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	SaturatedLiquidAndVaporMoleDensitiesAndPressure_FromTemperature(Double, Double)	Gets the saturated liquid mole density, the saturated vapor mole density, and the pressure for a given temperature. This is done by iteration, using multivariate Newton-Raphson. (Inherited from HelmholtzEquationOfStateOfPureFluids)
	SaturatedLiquidAndVaporMoleDensitiesAndPressure_FromTemperature(Double, Double, Double, Double)	Gets the saturated liquid mole density, the saturated vapor mole density, and the pressure for a given temperature. This is done by iteration, using multivariate Newton-Raphson. (Inherited from HelmholtzEquationOfStateOfPureFluids)
	SaturatedLiquidAndVaporMoleDensitiesAndTemperature_FromPressure	Gets the saturated liquid mole density, the saturated vapor mole density, and the temperature for a given pressure. This is done by iteration, using multivariate Newton-Raphson. (Inherited from HelmholtzEquationOfStateOfPureFluids)
	SaturatedLiquidMoleDensityEstimate_FromTemperature	Gets an estimate for the saturated liquid mole density in dependence on the temperature. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedMoleDensity_Type1	Evaluates saturated mole density correlation type 1. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedMoleDensity_Type2	Evaluates saturated mole density correlation type 2. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedMoleDensity_Type3	Evaluates saturated mole density correlation type 3. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedMoleDensity_Type4	Evaluates saturated mole density correlation type 4. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedMoleDensity_Type5	Evaluates saturated mole density correlation type 5. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedMoleDensity_Type6	Evaluates saturated mole density correlation type 6. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedVaporMoleDensityEstimate_FromTemperature	Gets an estimate for the saturated vapor mole density in dependence on the temperature. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedVaporPressure_Type1	Evaluates saturated vapor pressure correlation type 1. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedVaporPressure_Type2	Evaluates saturated vapor pressure correlation type 2. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedVaporPressure_Type3	Evaluates saturated vapor pressure correlation type 3. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedVaporPressure_Type4	Evaluates saturated vapor pressure correlation type 4. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedVaporPressure_Type5	Evaluates saturated vapor pressure correlation type 5. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedVaporPressure_Type6	Evaluates saturated vapor pressure correlation type 6. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedVaporPressureEstimate_FromTemperature	Gets an estimate for the saturated vapor pressure in dependence on the temperature. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedVaporPressureEstimateAndDerivativeWrtTemperature_FromTemperature	Gets an estimate for the saturated vapor pressure in dependence on the temperature as well as for the derivative of the saturated vapor pressure with respect to the temperature. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SaturatedVaporTemperature_FromPressure	Get the temperature at the liquid/vapor interface for a given pressure by iteration (Newton-Raphson). (Inherited from HelmholtzEquationOfStateOfPureFluids)
	SpeedOfSound_FromMassDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the speed of sound from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	SpeedOfSound_FromMassDensityAndTemperature(Double, Double)	Get the speed of sound from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	SpeedOfSound_FromMoleDensityAndTemperature(DimensionfulQuantity, DimensionfulQuantity)	Get the speed of sound from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	SpeedOfSound_FromMoleDensityAndTemperature(Double, Double)	Get the speed of sound from a given density and temperature. Attention - unchecked function: it is presumed, but not checked (!), that the given parameter combination describes a single phase fluid!. (Inherited from HelmholtzEquationOfState)
	SublimationPressure_Type1	Evaluates the sublimation-pressure equation of type 1. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SublimationPressure_Type2	Evaluates the sublimation-pressure equation of type 2. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SublimationPressure_Type3	Evaluates the sublimation-pressure equation of type 3. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SublimationPressureEstimate_FromTemperature	Gets an estimate of the sublimation pressure for the specified temperature. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SublimationPressureEstimateAndDerivativeWrtTemperature_FromTemperature	Gets an estimate of the sublimation pressure and its temperature derivative for the specified temperature. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	SublimationTemperatureEstimate_FromPressure	Gets an estimate of the sublimation temperature for a given pressure, using Newton-Raphson iteration. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	ToString	Returns a string that represents the current object. (Inherited from Object)

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Fields

	Name	Description
	_alpha0_Cosh	The prefactors outside and inside the argument of the Cosh terms in the equation of the ideal part of the reduced Helmholtz energy. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_alpha0_Exp	Prefactor and exponent of the exponential terms in the ideal part of the residual Helmholtz energy. Page 429 Table 6.1 in [2] (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_alpha0_n_const	The constant term in the equation of the ideal part of the reduced Helmholtz energy. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_alpha0_n_lntau	The term with the factor ln(tau) in the equation of the ideal part of the reduced Helmholtz energy. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_alpha0_n_tau	The term with the factor tau in the equation of the ideal part of the reduced Helmholtz energy. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_alpha0_n_taulntau	The term with the factor tau*ln(tau) in the equation of the ideal part of the reduced Helmholtz energy. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_alpha0_Poly	Stores polynomial coefficients for the ideal part of the reduced Helmholtz energy. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_alpha0_Sinh	The prefactors outside and inside the argument of the Sinh terms in the equation of the ideal part of the reduced Helmholtz energy. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_alphaR_Exp	Parameter for the exponential terms of the reduced Helmholtz energy. term = ni * tau^ti * delta^di * Exp(gi * delta^li) with gi normally equal to -1. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_alphaR_Gauss	Stores Gaussian-term coefficients for the residual part of the reduced Helmholtz energy. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_alphaR_Nonanalytical	Stores non-analytical-term coefficients for the residual part of the reduced Helmholtz energy. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_alphaR_Poly	Parameter for the polynomial terms of the reduced Helmholtz energy. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_meltingPressure_Coefficients	Stores the coefficient sets used by the melting-pressure equation. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_meltingPressure_ReducingPressure	Stores the reducing pressure used by the melting-pressure equation. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_meltingPressure_ReducingTemperature	Stores the reducing temperature used by the melting-pressure equation. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_meltingPressure_Type	Identifies the melting-pressure equation variant used by this fluid model. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_saturatedLiquidDensity_Coefficients	Stores coefficients for the saturated liquid density correlation. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_saturatedLiquidDensity_Type	Stores the saturated liquid density correlation type identifier. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_saturatedVaporDensity_Coefficients	Stores coefficients for the saturated vapor density correlation. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_saturatedVaporDensity_Type	Stores the saturated vapor density correlation type identifier. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_saturatedVaporPressure_Coefficients	Stores coefficients for the saturated vapor pressure correlation. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_saturatedVaporPressure_Type	Stores the saturated vapor pressure correlation type identifier. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_sublimationPressure_PolynomialCoefficients1	Stores the first coefficient set used by the sublimation-pressure equation. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_sublimationPressure_PolynomialCoefficients2	Stores the second coefficient set used by the sublimation-pressure equation. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_sublimationPressure_PolynomialCoefficients3	Stores the third coefficient set used by the sublimation-pressure equation. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_sublimationPressure_ReducingPressure	Stores the reducing pressure used by the sublimation-pressure equation. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_sublimationPressure_ReducingTemperature	Stores the reducing temperature used by the sublimation-pressure equation. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)
	_sublimationPressure_Type	Identifies the sublimation-pressure equation variant used by this fluid model. (Inherited from HelmholtzEquationOfStateOfPureFluidsBySpanEtAl)

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Remarks

References:

The source code was created automatically using the fluid file 'mdm.fld' from the following software:

TREND 3.0.: Span, R.; Eckermann, T.; Herrig, S.; Hielscher, S.; Jäger, A.; Thol, M. (2016): TREND.Thermodynamic Reference and Engineering Data 3.0.Lehrstuhl für Thermodynamik, Ruhr-Universität Bochum.

Further references (extracted from the fluid file):

EquationOfState (EOS): Thol, M., Dubberke, F.H, Vrabec, J., Span, R."Thermodynamic Properties of Octamethyltrisiloxane and Decamethyltetrasiloxane" to be submitted to J. Chem. Eng. Data, 2017

HeatCapacity (CPP): see EOS of Thol et al. (2017).

Saturated vapor pressure: see EOS of Thol et al. (2017).

Saturated liquid density: see EOS of Thol et al. (2017).

Saturated vapor density: see EOS of Thol et al. (2017).

Reference

Altaxo.Science.Thermodynamics.Fluids Namespace