CONTENTS Introduction��1��
0.1Physical chemistry��1��
0.1.1Contents of physical chemistry��1��
0.1.2Issues to be solved by physical chemistry��1��
0.1.3Advice for studying physical chemistry��2��
0.2Indication and operation of physical quantity��3��
0.2.1Indication of physical quantity��3��
0.2.2Operation of physical quantity��3��
Chapter 1The pVT properties of gases��4��
1.1State equation of the perfect gas��4��
1.1.1Empirical law of gas��4��
1.1.2State equation of the perfect gas��5��
1.1.3Model of the perfect gas��6��
1.2Mixture of the perfect gas��6��
1.2.1Composition of perfect gas mixture��6��
1.2.2Dalton��s law of partial pressures��7��
1.2.3Amagat��s law of partial volumes��8��
1.2.4Mean molar mass of mixed gas��8��
1.3Liquefaction of real gas and critical properties��9��
1.3.1Saturated vapor pressure of liquid��9��
1.3.2Liquefaction of real gas and critical properties��9��
1.4State equations of real gas��10��
1.4.1The van der Waals equation��10��
1.4.2The virial equation of state��11��
1.5The law of corresponding states��11��
1.5.1Compression factors��11��
1.5.2The law of corresponding states��12��
EXERCISES��12��
Chapter 2The first law of thermodynamics��14��
2.1The basic concept of thermodynamics��14��
2.1.1System and surroundings��14��
2.1.2Extensive property and intensive property of system��15��
2.1.3State and state function of system��15��
2.1.4Equilibrium state of thermodynamics��16��
2.1.5Process and path��16��
2.2The first law of thermodynamics��17��
2.2.1Heat��18��
2.2.2Work��18��
2.2.3Calculation of volume work��19��
2.2.4Thermodynamic energy��20��
2.2.5The first law of thermodynamics��21��
2.3The heat at constant volume, the heat at constant pressure and enthalpy��22��
2.3.1The heat at constant volume��22��
2.3.2The heat at constant pressure��22��
2.3.3Enthalpy��22��
2.3.4Hess��s Law��23��
2.4Heat capacity��24��
2.4.1Heat capacity��24��
2.4.2Relation between Cp, m and p��25��
2.4.3Empirical formula between Cp, m and T��25��
2.4.4Relation between Cp, m and CV, m��25��
2.4.5Joule experiment��26��
2.5Reversible process and equation of adiabatic reversible process of the perfect gas��29��
2.5.1Reversible process��29��
2.5.2Isothermal reversible process of the perfect gas��29��
2.5.3Adiabatic reversible process of the perfect gas��30��
2.6Phase transformation process��33��
2.6.1Phase and enthalpy of phase transition��33��
2.6.2Calculation of ΔH of phase transformation process��33��
2.7Standard molar enthalpy of reaction��35��
2.7.1Chemical stoichiometric number��35��
2.7.2Extent of a reaction��35��
2.7.3Molar enthalpy of reaction��36��
2.7.4Standard molar enthalpy of reaction��36��
2.8Standard molar enthalpy of formation and standard molar enthalpy of combustion��37��
2.8.1Standard molar enthalpy of formation��37��
2.8.2Standard molar enthalpy of combustion��38��
2.8.3The temperature—dependence of ΔrH��m(T)—Kirchhoff��s formula��39��
2.8.4The relation between Qp and QV��40��
2.8.5Maximum temperature of explosion and flame reaction��40��
2.9Throttling process and Joule��Thomson effect��41��
2.9.1Joule��Thomson experiment��41��
2.9.2Experiment result��41��
2.9.3Result analysis��41��
2.9.4Characteristics of throttling process��42��
2.9.5Joule��Thomson coefficient��42��
EXERCISES��42��
Chapter 3The second law of thermodynamics��45��
3.1Carnot cycle��45��
3.1.1Efficiency of heat engine��45��
3.1.2Carnot cycle��46��
3.1.3Carnot theorem��47��
3.2The second law of thermodynamics��48��
3.2.1Spontaneous process��48��
3.2.2Statements of the second law of thermodynamics��48��
3.2.3Essence of the second law of thermodynamics��49��
3.3Entropy and the principle of the increase of entropy��49��
3.3.1Entropy��49��
3.3.2Clausius inequality��50��
3.3.3The principle of the increase of entropy and entropy criterion of equilibrium��50��
3.4Calculation of entropy change of system��52��
3.4.1Calculation of ΔS of system in simple pVT process��52��
3.4.2Calculation of ΔS in phase transformation process��57��
3.5The Third law of thermodynamics and calculation of the entropy change of reaction��59��
3.5.1The Third law of thermodynamics��59��
3.5.2Conventional molar entropy and standard molar entropy��60��
3.5.3Calculation of ΔrS��m(T)��60��
3.6Helmholtz function and Gibbs function��61��
3.6.1Helmholtz function��61��
3.6.2Helmholtz function criterion��61��
3.6.3Gibbs function��62��
3.6.4Gibbs function criterion��62��
3.7Calculation of ΔA and ΔG��63��
3.7.1Simple pVT change process��63��
3.7.2Phase transformation process��64��
3.7.3Chemical change process��65��
3.8The fundamental equation of thermodynamics��67��
3.8.1The fundamental equation of thermodynamics��67��
3.8.2The relation of characteristic function��67��
3.8.3Gibbs-Helmholtz equation��68��
3.8.4Maxwell��s relations��68��
3.8.5Thermodynamic equation of state��69��
3.9Clapeyron equation��71��
3.9.1Condition for phase equilibrium of one��component system��71��
3.9.2Clapeyron equation��72��
3.9.3Clausius��Clapeyron equation��72��
EXERCISES��75��
Chapter 4The thermodynamics of multi��component systems��78��
4.1Mixture and solution��78��
4.1.1Composition scale of mixture��78��
4.1.2Composition scale of solute B in solution��79��
4.2Partial molar quantities��80��
4.2.1Definition of partial molar quantity��81��
4.2.2Collected formula of partial molar quantity��81��
4.2.3Gibbs��Duhem equation��82��
4.2.4Relations among different partial molar quantities��82��
4.3Chemical potential��83��
4.3.1Definition of chemical potential��83��
4.3.2Thermodynamic fundamental equation of multi��component homogeneous system changing of composition��83��
4.3.3Equilibrium criterion of material��84��
4.4Chemical potential of gas and fugacity��85��
4.4.1Expression of chemical potential of perfect gas��85��
4.4.2Expression of chemical potential of real gas and fugacity��86��
4.5Raoult��s Law and Henry��s Law��87��
4.5.1Gas��liquid equilibrium of liquid mixture or solution��87��
4.5.2Raoult��s law��87��
4.5.3Henry��s law��88��
4.6Mixture of ideal liquid��89��
4.6.1Definition and features of mixture of ideal liquid��89��
4.6.2Chemical potential of arbitrary component in mixture of ideal liquid��89��
4.6.3Mixing properties of mixture of ideal liquid��90��
4.6.4Gas��liquid equilibrium of mixture of ideal liquid��91��
4.7Ideal dilute solution��93��
4.7.1Definition and gas��liquid equilibrium of ideal dilute solution��93��
4.7.2Chemical potential of solvent and solute in ideal dilute solution��93��
4.7.3Distribution law of ideal dilute solution��95��
4.8Colligative properties of ideal dilute solution��96��
4.8.1Depression of vapor pressure (vapor pressure of solvent A)��96��
4.8.2Depression of freezing point (precipitation of solid pure solvent)��96��
4.8.3Elevation of boiling point (solute B: involatile)��97��
4.8.4Osmotic pressure��97��
4.9Real liquid mixture, real liquid solution and activity��99��
4.9.1Positive deviation and negative deviation��99��
4.9.2Activity and activity factor��99��
EXERCISES��101��
Chapter 5Chemical equilibrium��103��
5.1Standard equilibrium constant of chemical reaction��103��
5.1.1Molar Gibbs function change of chemical reaction��103��
5.1.2Definition of standard equilibrium constant of chemical reaction��104��
5.2Thermodynamic calculation of standard equilibrium constant��104��
5.2.1Calculate ΔrG��mT from ΔfG��mB,β,T��105��
5.2.2Calculate ΔrG��mT from ΔfH��mB,β,T, ΔcH��mB,β,T, S��mB,β,T and Cp,mB,β,T��105��
5.2.3Calculate ΔrG��m(T) from relative reactions��105��
5.3Relations between K��(T) and T��106��
5.3.1Relations between K��(T) and T��106��
5.3.2Integral formula of Van��t Hoff equation��107��
5.4Chemical equilibrium of perfect gas mixture reaction��108��
5.4.1Expression of standard equilibrium constant��108��
5.4.2Other expression of equilibrium constant��109��
5.5Chemical equilibrium of real gas mixture reaction��109��
5.6Van��t Hoff isothermal equation and determination of direction of chemical reaction��110��
5.7Calculation of equilibrium conversion of reactant and equilibrium composition of system��113��
5.7.1Definition of equilibrium conversion of reactant and equilibrium composition of system��113��
5.7.2Calculation of equilibrium conversion of reactant and equilibrium composition of system��113��
5.8The response of equilibrium to the conditions��114��
5.8.1Temperature��114��
5.8.2Pressure��115��
5.8.3Inert gas��116��
5.8.4Input material ratio��117��
5.9Chemical equilibrium of reaction of perfect gas and pure condensed phase��117��
5.9.1Expression of standard equilibrium constant��117��
5.9.2Dissociation pressure of pure solid compound��118��
EXERCISES��119��
Chapter 6Phase equilibrium��121��
6.1Phase rule��121��
6.1.1Basic concepts��121��
6.1.2Phase rule��122��
6.1.3Application of phase rule��122��
6.2p-T graph of one��component systems��124��
6.2.1p��T graph for water��125��
6.2.2p��T graph for carbon dioxide and supercritical CO2 fluid��126��
6.2.3p��T graph for sulfur��127��
6.3Two��component liquid��gas phase diagram of liquid full miscible system��127��
6.3.1Two��component liquid��gas phase diagram of ideal liquid mixture��128��
6.3.2Two��component liquid��gas phase diagram of real liquid mixture��131��
6.4Two��component liquid��gas phase diagram of liquid full immiscible and partially miscible system��134��
6.4.1Two��component boiling point��composition diagram of liquid full immiscible system��134��
6.4.2Two��component boiling point��composition diagram of liquid partially miscible system��135��
6.5Solid��liquid phase diagram of two��component system��139��
6.5.1Two��component solid��liquid phase diagram of solid full immiscible system��139��
6.5.2Thermal analysis method��140��
6.5.3Two��component solid��liquid phase diagram of condensed system forming compound��141��
EXERCISES��148��
Chapter 7Electrolyte solution��151��
7.1Electrolyte and types of electrolyte��151��
7.1.1Definition of electrolyte��151��
7.1.2Conducting mechanism of electrolyte solution��152��
7.1.3Types of electrolyte��152��
7.1.4Faraday��s Law��152��
7.2Transference numbers of ions��153��
7.2.1Electromigration��153��
7.2.2Transference Numbers of ions��153��
7.3Conductance, conductivity and molar conductivity��154��
7.3.1Conductance��154��
7.3.2Conductivity��154��
7.3.3Molar conductivity��155��
7.3.4Calculation of conductivity and molar conductivity��155��
7.3.5Relationship between κ and c or Λm and c��156��
7.3.6Law of the independent migration of ions—Kohlrausch��s law��157��
7.3.7Application of conductance measurement��158��
7.4Mean ionic activity of electrolyte��159��
7.4.1Mean ionic activity and mean ionic activity factor��159��
7.4.2Ionic strength of electrolyte solution��161��
7.5Ionic mutual attraction theory of strong electrolyte and Debye��Hückel limiting law��162��
7.5.1Ionic atmosphere model��162��
7.5.2Debye��Hückel limiting law��162��
EXERCISES��163��
Chapter 8Electrochemical system��165��
8.1Cell��165��
8.1.1Cell��166��
8.1.2Electrode��166��
8.1.3Cell diagram, electrode reaction and cell reaction of galvanic cell��166��
8.1.4Types of electrodes��167��
8.1.5Types of galva