Thermodynamics of Fluids

♨️Thermodynamics of Fluids Unit 8 – Phase Equilibria and Stability

Phase equilibria and stability are crucial concepts in thermodynamics, governing how substances transition between states. This unit explores the conditions for phase coexistence, the criteria for system stability, and the tools used to predict and analyze phase behavior. Students will learn about Gibbs free energy, chemical potential, and fugacity, as well as how to interpret phase diagrams. The unit also covers equilibrium conditions, stability criteria, and practical applications in various industries and natural systems.

Key Concepts and Definitions

  • Phase equilibrium occurs when two or more phases coexist in a system with no net transfer of mass or energy between them
  • Stability refers to a system's ability to maintain its state when subjected to small perturbations
  • Gibbs free energy (GG) is a thermodynamic potential that determines the stability and spontaneity of a process at constant temperature and pressure
    • Defined as G=HTSG = H - TS, where HH is enthalpy, TT is temperature, and SS is entropy
  • Chemical potential (μ\mu) is the partial molar Gibbs free energy and represents the change in GG when a component is added to a system
  • Fugacity (ff) is a measure of a component's tendency to escape from a phase, related to its chemical potential
  • Activity (aa) is the effective concentration of a component in a mixture, accounting for non-ideal behavior
  • Raoult's law states that the vapor pressure of a component in an ideal solution is proportional to its mole fraction in the liquid phase
  • Henry's law describes the solubility of a gas in a liquid at low concentrations, where the gas's partial pressure is proportional to its mole fraction in the liquid

Thermodynamic Principles

  • First law of thermodynamics states that energy cannot be created or destroyed, only converted from one form to another
    • Expressed as ΔU=Q+W\Delta U = Q + W, where ΔU\Delta U is the change in internal energy, QQ is heat added, and WW is work done
  • Second law of thermodynamics introduces the concept of entropy (SS), a measure of the system's disorder or randomness
    • States that the entropy of an isolated system always increases or remains constant
  • Third law of thermodynamics establishes the absolute zero of entropy, stating that a perfect crystal at 0 K has zero entropy
  • Fundamental equation of thermodynamics relates the change in internal energy to changes in entropy, volume, and composition
    • dU=TdSPdV+μidNidU = TdS - PdV + \sum \mu_i dN_i, where PP is pressure, VV is volume, and NiN_i is the number of moles of component ii
  • Maxwell relations are derived from the fundamental equation and relate partial derivatives of thermodynamic properties
  • Gibbs-Duhem equation constrains the changes in chemical potentials of components in a mixture at constant temperature and pressure

Phase Diagrams and Their Interpretation

  • Phase diagrams graphically represent the equilibrium states of a system as a function of thermodynamic variables (e.g., temperature, pressure, composition)
  • Common types include pressure-temperature (P-T), temperature-composition (T-x), and pressure-composition (P-x) diagrams
  • Phase boundaries separate regions of the diagram where different phases are stable
    • Represent conditions at which two or more phases coexist in equilibrium
  • Triple point is a unique condition where three phases coexist in equilibrium
  • Critical point represents the highest temperature and pressure at which vapor-liquid equilibrium can exist
  • Tie lines connect the compositions of coexisting phases in a two-phase region
  • Lever rule determines the relative amounts of each phase present at a given overall composition
  • Eutectic point is the lowest temperature at which a liquid phase can exist in a binary system

Gibbs Phase Rule

  • Gibbs phase rule relates the number of degrees of freedom (FF), components (CC), and phases (PP) in a system at equilibrium
    • Expressed as F=CP+2F = C - P + 2
  • Degrees of freedom represent the number of independent variables that can be changed without altering the number of phases in equilibrium
  • For a single-component system, the maximum number of degrees of freedom is 2 (usually temperature and pressure)
  • In a binary system, the maximum number of degrees of freedom is 3 (temperature, pressure, and composition)
  • Applying the phase rule helps determine the variance of a system and the conditions under which phase transitions occur

Equilibrium Conditions

  • Chemical equilibrium is achieved when the chemical potentials of each component are equal in all phases
    • Expressed as μiα=μiβ=...=μiπ\mu_i^\alpha = \mu_i^\beta = ... = \mu_i^\pi, where α\alpha, β\beta, and π\pi represent different phases
  • Thermal equilibrium requires the temperature to be uniform throughout the system
  • Mechanical equilibrium is reached when the pressure is the same in all phases
  • Gibbs energy minimization principle states that a system at constant temperature and pressure will minimize its Gibbs free energy at equilibrium
  • Common models for describing phase equilibria include ideal solution, regular solution, and activity coefficient models (e.g., Wilson, NRTL, UNIQUAC)
  • Equilibrium constants (KK) relate the activities or fugacities of components in different phases at equilibrium
    • For vapor-liquid equilibrium, Ki=yi/xiK_i = y_i / x_i, where yiy_i and xix_i are the mole fractions of component ii in the vapor and liquid phases, respectively

Stability Criteria

  • Thermodynamic stability requires that a system's Gibbs free energy is at a global minimum with respect to all possible perturbations
  • Mathematical conditions for stability involve the second derivatives of Gibbs free energy with respect to relevant variables
    • For example, (2G/T2)P>0(\partial^2 G / \partial T^2)_P > 0 and (2G/P2)T>0(\partial^2 G / \partial P^2)_T > 0 for thermal and mechanical stability, respectively
  • Spinodal curve represents the limit of metastability, beyond which a phase becomes unstable and spontaneously separates
  • Binodal curve (or coexistence curve) represents the equilibrium compositions of two phases in a binary system
  • Metastable regions exist between the binodal and spinodal curves, where a phase is stable with respect to small perturbations but unstable to large fluctuations
  • Gibbs stability criteria involve the determinant of the Hessian matrix of second derivatives of Gibbs free energy
    • A phase is stable if the determinant and all its principal minors are positive

Applications in Real Systems

  • Vapor-liquid equilibrium (VLE) is crucial in the design and operation of distillation columns, absorbers, and strippers
  • Liquid-liquid extraction (LLE) relies on the equilibrium distribution of a solute between two immiscible liquid phases
  • Solid-liquid equilibrium (SLE) is important in crystallization processes, such as in the pharmaceutical and food industries
  • Gas hydrates are solid compounds that form at high pressures and low temperatures, relevant in natural gas processing and flow assurance
  • Adsorption processes involve the equilibrium distribution of a solute between a fluid phase and a solid surface
  • Phase behavior of polymer solutions and blends is essential in the plastics and materials industries
  • Geochemical systems, such as mineral-fluid equilibria, are important in understanding the formation and evolution of Earth's crust
  • Biological systems, such as lipid membranes and protein folding, involve complex phase behavior and stability considerations

Problem-Solving Techniques

  • Identify the number of components, phases, and degrees of freedom using Gibbs phase rule
  • Determine the appropriate thermodynamic model for the system (e.g., ideal solution, activity coefficient models)
  • Write equilibrium conditions based on equality of chemical potentials or fugacities
  • Use mass balances and phase diagram information to set up a system of equations
  • Solve the system of equations numerically or analytically to obtain equilibrium compositions and phase amounts
  • Interpret the results in terms of phase stability, critical points, and other relevant features
  • Perform sensitivity analyses to assess the impact of uncertainties in model parameters or input data
  • Validate the results against experimental data or known phase behavior trends
  • Consider the limitations and assumptions of the chosen thermodynamic model and their implications for the solution


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© 2024 Fiveable Inc. All rights reserved.
AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.