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Physical Chemistry: Thermodynamics, Statistical Mechanics, and Kinetics

Physical Chemistry: Thermodynamics, Statistical Mechanics, and Kinetics

Author(s):
  • Andrew Cooksy
    • Author: Andrew Cooksy
    • ISBN:9789353063627
    • 10 Digit ISBN:9353063620
    • Price:Rs. 725.00
    • Pages:576
    • Imprint:Pearson Education
    • Binding:Paperback
    • Status:Available


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    Andrew Cooksy's clear teaching voice help students connect immediately with the subject matter while defusing some of their initial trepidation about physical chemistry. Through lively narrative and meticulous explanations of mathematical derivations, Physical Chemistry: Thermodynamics, Statistical Mechanics, and Kinetics engages students while fostering a sincere appreciation for the interrelationship between the theoretical and mathematical reasoning that underlies the study of physical chemistry. The author's engaging presentation style and careful explanations make even the most sophisticated concepts and mathematical details clear and comprehensible. 

     

    Table of Content

    "Physical Chemistry at the Macroscopic Scale:

    Statistical Mechanics, Thermodynamics, and Kinetics

     

    A Introduction: Tools from Math and Physics

    A.1 Mathematics

    A.2 Classical Physics

     

    I Extrapolation to Macroscopic Systems

    1 Introduction to Statistical Mechanics: Building Up to the Bulk

    1.1 Properties of the Microscopic World

    1.2 Bulk properties

    1.3 Entropy

    1.4 The ideal gas and translational states

    1.5 The ideal gas law

    Problems

     

    2 Partitioning the Energy

    2.1 Separation of Degrees of Freedom

    2.2 The equipartition principle

    2.3 Vibrational and rotational partition functions

    2.4 The Translational Density of States

    2.5 The translational partition function

    2.6 Temperature and the Maxwell-Boltzmann distribution

    Problems

     

    3 Statistical Mechanics and Molecular Interactions

    3.1 Extrapolation to many molecules

    3.2 Pressure of a non-ideal fluid

    3.3 Averaging the dipole-dipole potential

    3.4 Bose-Einstein and Fermi-Dirac statistics

     

    4 Mass Transport

    4.1 Statistics of molecular collisions

    4.2 Transport without external forces

    4.3 Transport with external forces

    Problems

     

    5 Energy transport

    5.1 Conduction, convection, and radiation

    5.2 Blackbody radiation

    5.3 Spectroscopic intensities

    5.4 Laser dynamics

    5.5 Spectroscopic linewidths

    5.6 Conclusion to Part IV: E, U, Ndof , S

    Problems

     

    II Non-Reactive Macroscopic Systems

    6 Introduction to Thermodynamics

    6.1 The first law of thermodynamics

    6.2 Approximations and assumptions

    6.3 Mathematical tools

    6.4 Computer simulations

    Problems

     

    7 Energy and Enthalpy

    7.1 Heat capacities

    7.2 Expansion of gases

    Problems

     

    8 Entropy

    8.1 Entropy of an ideal gas

    8.2 The second law of thermodynamics

    8.3 The third law of thermodynamics

    8.4 Ideal mixing

    Problems

     

    9 Phase Transitions and Phase Equilibrium

    9.1 Phase transitions

    9.2 Thermodynamics of phase transitions

    9.3 Chemical potentials

    9.4 Statistical mechanics of vaporization

    9.5 Phase diagrams

    Problems

     

    10 Solutions

    10.1 The standard states

    10.2 Statistical mechanics of solutions

    10.3 Thermodynamics of solutions

    10.4 Ionic solutions

    10.5 Applications of the activity

    10.6 Conclusion to Part V: E, U, Ndof , S

    Problems

     

    III Reactive Systems

    11 Chemical Thermodynamics

    11.1 Introduction to chemical reactions

    11.2 Enthalpies of reaction

    11.3 Spontaneous chemical reactions

    11.4 Chemical equilibrium

    Problems

     

    12 Elementary Reactions

    12.1 Reaction rates

    12.2 Simple collision theory

    12.3 Transition state theory

    12.4 Diffusion-limited rate constants

    12.5 Rate laws for elementary reactions

    Problems

     

    13 Multi-step Reactions

    13.1 Elements of multi-step reactions

    13.2 Approximations in kinetics

    13.3 Chain reactions

    Problems

     

    14 Reaction Networks

    14.1 Atmospheric chemistry

    14.2 Combustion chemistry

    14.3 Molecular astrophysics

    14.4 Enzyme catalysis

    14.5 Conclusion to the text"
     

    Salient Features

    "FLEXIBLE ORGANIZATION ACCOMMODATES THE CONTENT NEEDS AND TEACHING STYLES OF EACH SEMESTER/QUARTER SEQUENCE. Separation of Quantum Chemistry and Thermodynamics into distinct volumes provides the utmost in flexibility, allowing instructors to lead with their choice of Quantum-first or Thermo-first coverage. For students in need of a review at the start of the term/quarter, Chapter A: “Tools of Math and Physics” summarizes the prerequisite mathematics and physics assumed by the rest of the text. While the text reminds the student of specific equations from basic math and physics as needed, Chapter A underscores the fundamental nature of the course material by presenting at the outset the essential math and physics principles from which we construct chemical theory. Reflective of popular lecture strategies, chapter opening and closing features ground each topic within the larger framework of physical chemistry and help students stay oriented as they deepen their understanding. Opening features including a “Visual Roadmap” and “Context: Where Are We Now” show readers where they are within the text and relative to other physical chemistry topics. “Goal: Why Are We Here?” and “Learning Objectives” features prepare students for the work ahead and outline the skills students should expect to acquire from their study of the chapter. The concluding “Where Do We Go From Here” section at the end of each chapter reinforces student orientation and illuminates the intrinsic connection between concepts.."