当前课程知识点:Thermal Physics > Week 3: Chapter 2 The equilibrium theory of gas dynamics -- Basis of probability theory and Maxwell > 2.7 Three typical averages of molecular rates > 2.7-1Three statistical averages of molecular speed
2.7-1Three statistical averages of molecular speed.pdf---点此下载文件
下一节:2.7-1Three statistical averages of molecular speed-1.0 Introduction
-1.1 The macroscopic description method and the microscopic one
--1.1Macroscopic and microscopic description method
--1.1Macroscopic and microscopic description method
-1.2 Thermodynamic systems and equilibrium states
--1.2Thermodynamic systems and equilibrium states
--1.2Thermodynamic systems and equilibrium states
-1.3 Temperature, empirical temperature scale
--1.3Temperature, empirical thermometric scale
--1.3Temperature, empirical thermometric scale
-1.4 Absolute temperature scale
--1.4Absolute thermometric scale
--1.4Absolute thermometric scale
-1.5 Equation of state
--1.5-2Examples of an ideal gas equation
--1.5-2Examples of an ideal gas equation
-The thermometric scale and thermometers
-Homework of Chapter 1 Introduction -- the macro pa
-1.6 A microscopic model of matter
--1.6-2A microscopic model of matter
--1.6-2A microscopic model of matter
-1.7 A microscopic model of an ideal gas
--1.7A microscopic model of the ideal gas
--1.7A microscopic model of the ideal gas
-1.8 A preliminary theory of microscopic description of an ideal gas
--1.8-1Preliminary theory of microscopic description of the ideal gases (1)
--1.8-1Preliminary theory of microscopic description of the ideal gases (1)
--1.8-2Preliminary theory of microscopic description of the ideal gases (2)
--1.8-2Preliminary theory of microscopic description of the ideal gases (2)
--1.8-3Preliminary theory of microscopic description of the ideal gases (3)
--1.8-3Preliminary theory of microscopic description of the ideal gases (3)
--1.8-4Examples of average translational kinetic energy and root-mean-square speed
--1.8-4Examples of average translational kinetic energy and root-mean-square speed
-1.9 The inter-molecular kinetic energy of real gas
--1.9Intermolecular forces and potential energy of real gas
--1.9Intermolecular forces and potential energy of real gas
-1.10 Van der Waals equation
-Homework of Week 2: Chapter 1 Introduction -- the micro part
-2.1 Molecular dynamics theory and statistical Physics
--2.1Molecular dynamics theory and statistical physics
--2.1Molecular dynamics theory and statistical physics
-2.2 The basics of probability theory
--2.2The basics of probability theory
--2.2The basics of probability theory
-2.3 Probability distribution function
--2.3Probability distribution function
--2.3Probability distribution function
-2.4 Molecular beam experiments
--2.4Molecular beam experiments
--2.4Molecular beam experiments
-2.5 Velocity space
-2.6 Maxwell rate distribution
--2.6-1Maxwell speed distribution
--2.6-1Maxwell speed distribution
--2.6-2An example of the distribution of translational kinetic energy of molecules
--2.6-2An example of the distribution of translational kinetic energy of molecules
-2.7 Three typical averages of molecular rates
--2.7-1Three statistical averages of molecular speed
--2.7-1Three statistical averages of molecular speed
--2.7-2An example of molecular distribution
--2.7-2An example of molecular distribution
--2.7-3Examples of Maxwell speed distribution
--2.7-3Examples of Maxwell speed distribution
-Three typical statistical averages of speed
-Homework of Week 3: Basis of probability theory and Maxwell
-2.8 Maxwell velocity distribution
-- 2.8Maxwell velocity distribution
--2.8Maxwell velocity distribution
-2.9 Velocity component distribution and velocity distribution relative to the most probable rate
--2.9The velocity component and the speed distribution relative to the most probable speed
--2.9The velocity component and the speed distribution relative to the most probable speed
-2.10 The number of gas molecules hitting the wall from Maxwell velocity distribution and pressure fo
--2.10Deriving the formula for the wall-hitting number and pressure of gas molecules from Maxwell velo
--2.10Deriving the formula for the wall-hitting number and pressure of gas molecules from Maxwell velo
--2.10-2An example of a small hole discharge
--2.10-2An example of a small hole discharge
-2.11 Isothermal atmospheric pressure formula
--2.11Isothermal barometric formula
--2.11Isothermal barometric formula
--2.11-2Examples of an isothermal barometric formula
--2.11-2Examples of an isothermal barometric formula
-2.12 Boltzmann distribution
-2.13 The radial distribution of suspended particles in the rotating body and super-centrifugal techn
--2.13Radial distribution of suspended particles in a rotator and ultracentrifugation
--2.13Radial distribution of suspended particles in a rotator and ultracentrifugation
-Most probable velocity and most probable speed
-Homework of Week 4: Chapter 2 Equilibrium state theory of gas dynamics -- Maxwell velocity distribution and Bol
-2.14 Heat capacity and internal energy of a monatomic ideal gas
--2.14The heat capacity and internal energy of the monatomic ideal gas
--2.14The heat capacity and internal energy of the monatomic ideal gas
-2.15 Degrees of freedom and degrees of freedom
--2.15Degree of Freedom and the Number of It
--2.15Degree of Freedom and the Number of It
-2.16 Energy equipartition theorem
--2.16Theorem of equipartition of energy
--2.16Theorem of equipartition of energy
--2.16-2Examples of the Theorem of Equipartition of Energy
--2.16-2Examples of the Theorem of Equipartition of Energy
-2.17 Limitations of the equipartition theorem
--2.17The Limitation of the Theorem of Equipartition of Energy
--2.17The Limitation of the Theorem of Equipartition of Energy
-Equipartition theorem of energy
-Homework of Week 5 Equipartition theorem of energy
-3.1 Macroscopic law of viscosity phenomena
--3.1The macro law of the phenomenon of viscosity
--3.1The macro law of the phenomenon of viscosity
-3.2 Macroscopic law of heat conduction phenomenon
--3.2The macro law of thermal conduction phenomenon
--3.2The macro law of thermal conduction phenomenon
-3.3 Macroscopic law of diffusion phenomenon
--3.3The macro law of diffusion phenomenon
--3.3The macro law of diffusion phenomenon
--3.3-2Examples of the macro law of gas transport phenomenon
--3.3-2Examples of the macro law of gas transport phenomenon
-3.4 The mean free path of a gas molecule
--3.4-1Mean free path of gas molecules
--3.4-1Mean free path of gas molecules
--3.4-2The mean free path examples of gas molecules
--3.4-2The mean free path examples of gas molecules
-3.5 The distribution of gas molecules in a free path
--3.5Distribution of gas molecules in free path
--3.5Distribution of gas molecules in free path
-3.6 Derivation of gas transport coefficient
--3.6-1Derivation of gas transport coefficient: viscosity coefficient of gas
--3.6-1Derivation of gas transport coefficient: viscosity coefficient of gas
--3.6-2Derivation of gas transport coefficient thermal conductivity coefficient of gas
--3.6-2Derivation of gas transport coefficient thermal conductivity coefficient of gas
--3.6-3Derivation of gas transport coefficient and diffusion coefficient of gas
--3.6-3Derivation of gas transport coefficient and diffusion coefficient of gas
-3.7 Thermal conductivity in rarefied gases
--3.7Heat conductivity in thin gas
--3.7Heat conductivity in thin gas
-Homework of Chapter 3
-4.1 Reversible and irreversible processes
--4.1Reversible and Irreversible Process
--4.1Reversible and Irreversible Process
-4.2 Work and heat
-4.3 The first law of thermodynamics
--4.3-1First Law of Thermodynamics
--4.3-1First Law of Thermodynamics
-4.4 The heat capacity and enthalpy
--4.4Heat capacity and enthalpy
--4.4Heat capacity and enthalpy
-4.5 Internal energy of ideal gases and Joule experiment
--4.5Internal energy of the ideal gas and Joule experiment
--4.5Internal energy of the ideal gas and Joule experiment
-4.6 The same-body, isobaric, and isothermal processes of an
--4.6-1Isochoric, Isobaric and Isothermal Processes of the Ideal Gas
--4.6-1Isochoric, Isobaric and Isothermal Processes of the Ideal Gas
--4.6-2Examples of Isochoric, Isobaric and Isothermal Processes of the Ideal Gas
--4.6-2Examples of Isochoric, Isobaric and Isothermal Processes of the Ideal Gas
-Change in adiabatic free expansion temperature of a real gas
-Homework of Chapter 4 The first Law of thermodynamics
-4.7 The adiabatic process for an ideal gas
--4.7-1Adiabatic process of the ideal gas
--4.7-1Adiabatic process of the ideal gas
--4.7-2Examples of adiabatic process 1
--4.7-2Examples of adiabatic process 1
--4.7-3Examples of adiabatic process 2
--4.7-3Examples of adiabatic process 2
--4.7-4Examples of adiabatic process 3
--4.7-4Examples of adiabatic process 3
--4.7-5Example of the First Law of Thermodynamics
--4.7-5Example of the First Law of Thermodynamics
-4.8 The multiparty process for an ideal gas
--4.8-1The Ideal Gas Polytropic Process
--4.8-1The Ideal Gas Polytropic Process
--4.8-2Example of polytropic process
--4.8-2Example of polytropic process
--4.8-3Example of non-polytropic process
--4.8-3Example of non-polytropic process
-4.9 Heat engine
--4.9-1Heat engine, Carnot heat engine
--4.9-1Heat engine, Carnot heat engine
--4.9-2Examples of Heat Engine 1
--4.9-2Examples of Heat Engine 1
--4.9-3Examples of Heat Engine 2
--4.9-3Examples of Heat Engine 2
-4.10 Refrigeration cycle
--4.10-1Refrigeration cycle, Carnot refrigeration cycle
--4.10-1Refrigeration cycle, Carnot refrigeration cycle
--4.10-2Examples of Refrigerator
--4.10-2Examples of Refrigerator
-4.11 Joule-Thomson experiment (throttling)
-Homework of Week 8
-5.1 Two statements and equivalence of the second law of thermodynamics
--5.1-1Two statements of the second law of thermodynamics and their equivalence
--5.1-1Two statements of the second law of thermodynamics and their equivalence
--5.1-2Examples of the second law of thermodynamics
--5.1-2Examples of the second law of thermodynamics
-5.2 Carnot theorem
--5.2-2Examples of Carnot theorem
--5.2-2Examples of Carnot theorem
-5.3 Clausius equation
-5.4 Clausius entropy and its calculation
--5.4Clausius entropy and its calculation
--5.4Clausius entropy and its calculation
-Homework of Week 9
-5.5 Principle of entropy increase
--5.5Principle of entropy increase
--5.5Principle of entropy increase
-5.6 The mathematical expression of the second law of thermodynamics
--5.6A mathematical expression for the second law of thermodynamics
--5.6A mathematical expression for the second law of thermodynamics
-5.7 Statistical significance of the second Law of thermodynamics
--5.7Statistical significance of the second Law of thermodynamics
--5.7Statistical significance of the second Law of thermodynamics
-5.8 The microscopic meaning of entropy
--5.8The microscopic meaning of entropy
--5.8The microscopic meaning of entropy
-The Principle of entropy Increase
-Homework of Week 10
-6.1 Surface tension and surface energy
--6.1Surface Tension and Surface Energy
--6.1Surface Tension and Surface Energy
-6.2 Additional pressure at bending level
--6.2The Additional Pressure of the Curved Liquid Surface
--6.2The Additional Pressure of the Curved Liquid Surface
-6.3 Wetting and non-wetting and capillary phenomenon
--6.3-1Wetting and Nonwetting Capillary Phenomena
--6.3-1Wetting and Nonwetting Capillary Phenomena
--6.3-2Examples of Capillary Phenomenon and the Additional Pressure of the Curved Liquid Surface
--6.3-2Examples of Capillary Phenomenon and the Additional Pressure of the Curved Liquid Surface
-6.4 Gasification and condensation
--6.4-1Gasification and Condensation 1
--6.4-1Gasification and Condensation 1
--6.4-2Gasification and Condensation 2
--6.4-2Gasification and Condensation 2
--6.4-3Gasification and Condensation 3
--6.4-3Gasification and Condensation 3
-6.5 Real gas isotherm
-6.6 Van der Gas isotherm
-6.7 Solid liquid phase change, gas-solid phase change and phase diagram
--6.7Solid-liquid Phase Transition, Solid-gas Phase Transition and Phase Diagram
--6.7Solid-liquid Phase Transition, Solid-gas Phase Transition and Phase Diagram
-6.8 Clapeyron equation
--6.8-2The Examples of Clapeyron's Equation
--6.8-2The Examples of Clapeyron's Equation
-Solid-Liquid transition change of water
-Homework for week 11
-Examination of Thermal Physics