Lect-19. In this lecture...

Similar documents
Chapter 3 PROPERTIES OF PURE SUBSTANCES SUMMARY

Chemistry. Lecture 10 Maxwell Relations. NC State University

Clausius Clapeyron Equation

Thermodynamic Variables and Relations

Some properties of the Helmholtz free energy

Chapter 3 PROPERTIES OF PURE SUBSTANCES

Chapter 3 PROPERTIES OF PURE SUBSTANCES

Thermodynamics I. Properties of Pure Substances

Thermodynamics of solids 5. Unary systems. Kwangheon Park Kyung Hee University Department of Nuclear Engineering

Real Gas Thermodynamics. and the isentropic behavior of substances. P. Nederstigt

Chapter 12 PROPERTY RELATIONS. Department of Mechanical Engineering

Chapter 3 PROPERTIES OF PURE SUBSTANCES

PROPERTIES OF PURE SUBSTANCES. Chapter 3. Mehmet Kanoglu. Thermodynamics: An Engineering Approach, 6 th Edition. Yunus A. Cengel, Michael A.

10, Physical Chemistry- III (Classical Thermodynamics, Non-Equilibrium Thermodynamics, Surface chemistry, Fast kinetics)

Introduction to Thermodynamic Cycles Part 1 1 st Law of Thermodynamics and Gas Power Cycles

4 Fundamentals of Continuum Thermomechanics

CHAPTER 3 LECTURE NOTES 3.1. The Carnot Cycle Consider the following reversible cyclic process involving one mole of an ideal gas:

Web Resource: Ideal Gas Simulation. Kinetic Theory of Gases. Ideal Gas. Ideal Gas Assumptions

Chapter 8 Thermodynamic Relations

Thermodynamics I Chapter 2 Properties of Pure Substances

Outline. Example. Solution. Property evaluation examples Specific heat Internal energy, enthalpy, and specific heats of solids and liquids Examples

Physics 360 Review 3

2. Under conditions of constant pressure and entropy, what thermodynamic state function reaches an extremum? i

CHAPTER. Properties of Pure Substances

Name: Discussion Section:

Chapter 3. Property Relations The essence of macroscopic thermodynamics Dependence of U, H, S, G, and F on T, P, V, etc.

R13. II B. Tech I Semester Regular Examinations, Jan THERMODYNAMICS (Com. to ME, AE, AME) PART- A

ESCI 341 Atmospheric Thermodynamics Lesson 12 The Energy Minimum Principle

Modeling Hydraulic Accumulators for use in Wind Turbines

Chapter 1 Introduction and Basic Concepts


1 st Law: du=dq+dw; u is exact Eq. 2.8 du=dq rev -pdv (expansion only) p. 56. (δp/δt) g =η/v Eq. 2.40

Relation between compressibility, thermal expansion, atom volume and atomic heat of the metals

CM 3230 Thermodynamics, Fall 2016 Lecture 16

Chapter 4: Properties of Pure Substances. Pure Substance. Phases of a Pure Substance. Phase-Change Processes of Pure Substances

CHEMICAL ENGINEERING THERMODYNAMICS. Andrew S. Rosen

Chem 4521 Kinetic Theory of Gases PhET Simulation

LECTURE NOTE THERMODYNAMICS (GEC 221)

The Maxwell Relations

Pure Substance. Properties of Pure Substances & Equations of State. Vapour-Liquid-Solid Phase Equilibrium

MAHALAKSHMI ENGINEERING COLLEGE

Chapter 14 Thermal Physics: A Microscopic View

Kinetic Theory. Reading: Chapter 19. Ideal Gases. Ideal gas law:

The Second Law of Thermodynamics (Chapter 4)

Chapter 7: The Second Law of Thermodynamics

A one-dimensional analytical calculation method for obtaining normal shock losses in supersonic real gas flows

OCN 623: Thermodynamic Laws & Gibbs Free Energy. or how to predict chemical reactions without doing experiments

Chemical Engineering Thermodynamics

Lecture Phase transformations. Fys2160,

Chapter 1 Solutions Engineering and Chemical Thermodynamics 2e Wyatt Tenhaeff Milo Koretsky

SELECTION, SIZING, AND OPERATION OF CONTROL VALVES FOR GASES AND LIQUIDS Class # 6110

fiziks Institute for NET/JRF, GATE, IIT-JAM, JEST, TIFR and GRE in PHYSICAL SCIENCES

Pure Substance. Properties of Pure Substances & Equations of State. Vapour-Liquid-Solid Phase Equilibrium

even at constant T and P, many reversible and irreversible changes of thermodynamic state may

HOMOGENEOUS CLOSED SYSTEM

Chapter 13. Up to this point, we have limited our consideration to GAS MIXTURES. Objectives


Module 5 : Electrochemistry Lecture 21 : Review Of Thermodynamics

ME 2202 ENGINEERING THERMODYNAMICS TWO MARKS QUESTIONS AND ANSWERS UNIT I BASIC CONCEPTS AND FIRST LAW

General Lorentz Boost Transformations, Acting on Some Important Physical Quantities

Lecture 44: Review Thermodynamics I

Homework Week 8 G = H T S. Given that G = H T S, using the first and second laws we can write,

1 mol ideal gas, PV=RT, show the entropy can be written as! S = C v. lnt + RlnV + cons tant

Chapter 5. Simple Mixtures Fall Semester Physical Chemistry 1 (CHM2201)

Algorithms and Data Structures 2014 Exercises and Solutions Week 14

Thermodynamics Qualifying Exam Study Material

Identify the intensive quantities from the following: (a) enthalpy (b) volume (c) refractive index (d) none of these

4.1 LAWS OF MECHANICS - Review

arxiv:physics/ v4 [physics.class-ph] 27 Mar 2006

Lecture Ch. 2a. Lord Kelvin (a.k.a William Thomson) James P. Joule. Other Kinds of Energy What is the difference between E and U? Exact Differentials

Chapter 3- Answers to selected exercises

UBMCC11 - THERMODYNAMICS. B.E (Marine Engineering) B 16 BASIC CONCEPTS AND FIRST LAW PART- A

WHY SHOULD WE CARE ABOUT THERMAL PHENOMENA? they can profoundly influence dynamic behavior. MECHANICS.

Simulations of bulk phases. Periodic boundaries. Cubic boxes

Physics Nov Cooling by Expansion

Section 6: PRISMATIC BEAMS. Beam Theory

SF Chemical Kinetics.

ME6301- ENGINEERING THERMODYNAMICS UNIT I BASIC CONCEPT AND FIRST LAW PART-A

Section 3 Entropy and Classical Thermodynamics

First Law CML 100, IIT Delhi SS. The total energy of the system. Contribution from translation + rotation + vibrations.

Outline Review Example Problem 1. Thermodynamics. Review and Example Problems: Part-2. X Bai. SDSMT, Physics. Fall 2014

Basic Thermodynamics Module 1

Lecture 3 Clausius Inequality

Department of Mechanical Engineering ME 322 Mechanical Engineering Thermodynamics. Calculation of Entropy Changes. Lecture 19

The Chemical Potential

Course: MECH-341 Thermodynamics II Semester: Fall 2006

ISENTHALPIC THROTTLING (FREE EXPANSION) AND THE JOULE-THOMSON COEFFICIENT

Thermodynamics (Lecture Notes) Heat and Thermodynamics (7 th Edition) by Mark W. Zemansky & Richard H. Dittman

Earlier Lecture. Basics of Refrigeration/Liquefaction, coefficient of performance and importance of Carnot COP.

Liquids and Solids. Copyright The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

C v & Thermodynamics Relationships

d dt T R m n p 1. (A) 4. (4) Carnot engine T Refrigerating effect W COPref. = 1 4 kw 5. (A)

Comparative evaluation of the Joule-Thomson coefficient for CO 2(g) and N 2(g) distributed by air liquide PLC, Onitsha Anambra State, Nigeria

1. Thermodynamics 1.1. A macroscopic view of matter

Chapter 2 Gibbs and Helmholtz Energies

Lecture 4 Clausius Inequality

16 Free energy and convex analysis. Summary Helmholtz free energy A tells us about reversible work under isothermal condition:

MS212 Thermodynamics of Materials ( 소재열역학의이해 ) Lecture Note: Chapter 7

Chapter 1. The Properties of Gases Fall Semester Physical Chemistry 1 (CHM2201)

Pressure Volume Work 2

Transcription:

19 1

In this lecture... Helmholtz and Gibb s functions Legendre transformations Thermodynamic potentials The Maxwell relations The ideal gas equation of state Compressibility factor Other equations of state Joule-Thomson coefficient 2

Helmholtz and Gibbs functions Lect-19 We hae already discussed about a combination property, enthalpy, h. We now introduce two new combination properties, Helmholtz function, a and the Gibbs function, g. Helmholtz function, a: indicates the maximum work that can be obtained from a system. It is expressed as: a = u Ts 3

Helmholtz and Gibbs functions Lect-19 It can be seen that this is less than the internal energy, u, and the product Ts is a measure of the unaailable energy. Gibbs function, g: indicates the maximum useful work that can be obtained from a system. It is expressed as: g = h Ts This is less than the enthalpy. 4

Helmholtz and Gibbs functions Two of the Gibbs equations that were deried earlier (Tds relations) are: du = Tds Pd dh = Tds + dp The other two Gibbs equations are: a = u Ts g = h Ts Differentiating, da = du Tds sdt dg = dh Tds sdt Lect-19 5

Legendre transformations A simple compressible system is characterized completely by its energy, u (or entropy, s) and olume, : 6 Lect-19 u s s T P u s Pd du Tds u s s u P s u T Pd Tds du s u u = = + = = = = = = T 1 such that ), ( Alternatiely, in the entropy representation, such that ), (

Legendre transformations Any fundamental relation must be expressed in terms of its proper ariables to be complete. Thus, the energy features entropy, rather than temperature, as one of its proper ariables. Howeer, entropy is not a conenient ariable to measure experimentally. Therefore, it is conenient to construct other related quantities in which entropy is a dependent instead of an independent ariable. 7

Legendre transformations Lect-19 For example, we define the Helmholtz free energy as, a = u Ts, so that for a simple compressible system we obtain a complete differential of the form a = u Ts da = sdt Pd a a Such that s = P = T T This state function is clearly much more amenable to experimental manipulation than the internal energy. 8

Thermodynamic potentials State functions obtained by means of Legendre transformation of a fundamental relation are called thermodynamic potentials. Eg. h, s, a and g. This is because the roles they play in thermodynamics are analogous to the role of the potential energy in mechanics. Each of these potentials proides a complete and equialent description of the equilibrium states of the system because they are all deried from a fundamental relation. 9

Thermodynamic potentials Lect-19 Using the Legendre transformations discussed aboe, we can summarize the following thermodynamic potentials and the corresponding state ariables. State Variables (u, ) (T, ) (T, P) (s, P) Thermodynamic potentials Entropy, s Helmholtz function, a = u Ts Gibbs function, g = h Ts Enthalpy, h = u + P 10

The Maxwell relations The Maxwell relations: equations that relate the partial deriaties of properties P,, T, and s of a simple compressible system to each other. These equations are deried by using the exactness of the differentials of the thermodynamic properties. Maxwell relations can be obtained by applying the Legendre transformations for the four Gibb s equations. 11

The Maxwell relations The Gibb s equations (for a and g) reduce to da = sdt Pd dg = sdt +dp The four equations discussed aboe are of the form: dz = where, Mdx M y Ndy Since, u, h, a, and g are properties and they hae exact differentials. + x = N x y 12

The Maxwell relations Applying the aboe to the Gibbs equations, 13 Lect-19 P T T P s s T P s T P s s P T s P T = = = = The Maxwell relations.

The Maxwell relations The Maxwell relations are aluable thermodynamic relations as they proide a means of measuring changes in entropy using P, and T. The Maxwell relations gien aboe are limited to simple compressible systems. Similar relations can be written just as easily for non-simple systems such as those inoling electrical, magnetic, and other effects. 14

The ideal gas equation of state Lect-19 Any equation that relates the pressure, temperature, and specific olume of a substance is called an equation of state. The simplest and best-known equation of state for substances in the gas phase is the ideal-gas equation of state, which is P = RT Where P is the absolute pressure, T is the absolute temperature, is the specific olume, and R is the gas constant. 15

Compressibility factor Real gases deiate substantially from the ideal gas behaiour depending upon the pressure and temperature. This can be accounted for by using a factor known as the Compressibility factor, Z: Z = P/RT For ideal gases, Z=1, whereas for real gases Z may be > or < 1. The farther away Z is from unity, the more the gas deiates from ideal-gas behaiour. 16

Compressibility factor Gases behae differently at different pressures and temperatures. But when normalised with respect to the critical pressure and temperature, their behaiour is the same. Therefore normalising, P R = P/P cr and T R = T/T cr where, P R is the reduced pressure and T R is the reduced temperature. 17

Compressibility factor The Z factor is approximately the same for all gases at the same reduced temperature and pressure. This is called the principle of corresponding states. From experimental data there are generalised compressibility charts aailable that can be used for all gases. 18

Compressibility factor 19

Compressibility factor The following obserations can be made from the generalized compressibility chart: At ery low pressures (P R «1), gases behae as an ideal gas regardless of temperature. At high temperatures (T R >2), ideal-gas behaiour can be assumed with good accuracy regardless of pressure (except when P R»1). The deiation of a gas from ideal-gas behaiour is greatest in the icinity of the critical point. 20

Other equations of state Though the ideal gas equation is simple, its applicability is often limited. It is therefore desirable to hae an equation that can be used without too many limitations. Many such equations hae been formulated, most of which are much more complicated than the ideal gas equation. The an der Waal s equation is one of the earliest, Beattie-Bridgeman equation is the most popular and Benedict-Webb-Rubin equation is the most recent and accurate equation. 21

Other equations of state Lect-19 an der Waal s equation: included two of the effects not considered in the ideal-gas model, the intermolecular attraction forces, a/ 2 and the olume occupied by the molecules themseles, b. a p + = 2 ( b) RT The constants a and b can be determined for any substance from the critical point data alone. 22

Other equations of state The Beattie-Bridgeman equation, is an equation of state based on fie experimentally determined constants. It is expressed as: P = R T u 2 Where, 1 A = A T 0 c 3 1 ( + B) a and B A 2 = B 0 1 b 23

Other equations of state The equation of state can be in general expressed in a series as: P = RT + a( T ) b( T ) 3 c( T ) 4 d( T ) 5 + + + + 2 This and similar equations are called the irial equations of state. The coefficients a(t), b(t), c(t), and so on, that are functions of temperature alone are called irial coefficients.... 24

Other equations of state These coefficients can be determined experimentally or theoretically from statistical mechanics. As the pressure approaches zero, all the irial coefficients will anish and the equation will reduce to the ideal-gas equation of state. 25

The Joule Thomson coefficient Lect-19 There is a pressure drop associated with flow through a restriction like ales, capillary tube, porous plug etc. The enthalpy of the fluid remains a constant. The temperature of a fluid may increase, decrease, or remain constant during a throttling process. The behaiour of fluids in such flows is described by the Joule-Thomson coefficient. 26

The Joule Thomson coefficient Lect-19 The Joule-Thomson coefficient is defined as: T µ = P h The Joule-Thomson coefficient is a measure of the change in temperature with pressure during a constant-enthalpy process. < µ = > 0 0 0 temperature increases temperature remains constant temperature decreases 27

The Joule Thomson coefficient Lect-19 P 2, T 2 (Varied) P 1, T 1 (Fixed) T Exit States Inlet State h= constant P 1 P The deelopment of an h = constant line on a P-T diagram 28

The Joule Thomson coefficient Some h= constant lines on the T-P diagram pass through a point of zero slope or zero Joule-Thomson coefficient. The line that passes through these points is called the inersion line, and the temperature at a point where a constant-enthalpy line intersects the inersion line is called the inersion temperature. The slopes of the h=constant lines are negatie (μ<0) at states to the right of the inersion line and positie (μ>0) to the left of the inersion line. Lect-19 29

The Joule Thomson coefficient Lect-19 T Maximum inersion temperature μ>0 μ<0 h=const. Inersion line < µ = > 0 0 0 temperature increases temperature remains constant temperature decreases P Constant enthalpy lines on a T-P diagram 30

In this lecture... Helmholtz and Gibb s functions Legendre transformations Thermodynamic potentials The Maxwell relations The ideal gas equation of state Compressibility factor Other equations of state Joule-Thomson coefficient 31

In the next lecture... Sole numerical problems Gas power cycles: Otto, Diesel, dual cycles Gas power cycles: Brayton cycle, ariants of Brayton cycle Vapour power cycle: Rankine cycle Thermodynamic property relations 32

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback