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Phase Equilibrium

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Title: Phase Equilibrium


1
Phase Equilibrium
  • When a gas and a liquid phase which are not
    thermodynamically in equilibrium are brought into
    close contact, transfer of one or more components
    may occur from the gas phase to the liquid or,
    vice versa, by the mechanism of molecular
    diffusion.
  • Mass transfer by molecular diffusion is the basic
    physical mechanism underlying many important
    areas of soil science, petroleum engineering,
    chemical engineering, biotechnology and nuclear
    engineering.
  • In this experiment, a method for determining
    diffusion coefficients of Carbon dioxide gas in
    Stoddard solvent at constant volume, pressure and
    temperature is developed using Integral Phase
    Equilibria Unit.

2
Objective
  • Determine
  • diffusion coefficient,
  • Solubility,
  • Henrys Constant
  • The enthalpy of solution of carbon dioxide in
    Stoddard solvent in the range of 18 - 35C and at
    1.0 atmosphere pressure.

3
Introduction
  • Diffusion Coefficient
  • Measures the rate of diffusion
  • Time-dependent
  • Solubility
  • Measures maximum amount of gas dissolved in
    liquid
  • Time-independent
  • Henrys Law constant
  • Dissolved gas in liquid is proportional to
    partial pressure in vapor phase
  • Heat of mixing
  • Correlation between Henrys Law constant and T

4
Determination of diffusion coefficient from
experimental data
A number of mathematical models have been
proposed to determine the diffusion coefficients
from experimental volumetime profiles, however
all these models are developed from the equation
of continuity for the solute component
Gas phase
C
Cav
where r Rate of reaction (kg/m3s) J Mass
transfer by the mechanism of molecular diffusion
(kg/m2s) v Molar volume (m3)
Interface
Z Z(t) Z0
5
  • Referring to Fig 12
  • for a one-dimensional diffusion cell
  • absence of chemical reaction,
  • movement of the interface in the boundary
    conditions of the system, in which a component in
    the gas phase is absorbed into a liquid phase
    starting at time zero and continuing at longer
    times.
  • Based upon a model proposed by Higbie
    (penetration theory)
  • the liquid interface is thus always at
    saturation, since the molecules can diffuse in
    the liquid phase away from the interface only at
    rates which are extremely low with respect to the
    rate at which gaseous molecules can be added to
    the interface.
  • It is also assumed that the distance between the
    interface and the bottom of the cell is
    semi-infinite that is, diffusion is slow enough
    that the concentration at the bottom of the cell
    is negligible compared to the concentration at
    the interface.
  • According to the film theory
  • the gas and the liquid phases at the interface
    are thermodynamically in equilibrium, i.e. the
    interface concentration of the solute, Ci remains
    unchanged as long as temperature and pressure of
    the system are kept constant.

Gas V104 CC
Ci
Stoddard Solvent V100 CC
Z(t)
C(t,Z)
Z
6
where C Concentration of dissolved CO2 in the
liquid phase at Z and t. Z Distance in cm
traveled from the liquid interface. t time D12
Diffusion coefficient of species 1 in 2.
  • Thus the unsteady-state differential equation
    representing concentration changes with time and
    position is
  • Solution of Ficks 2nd Law using the boundary
    conditions described is
  • Solve for the number of moles added up to a time
    t
  • If one plots NT versus t1/2, the slope of this
    line is equal to

The boundary conditions are Z 0 C Ci
Z ? 8 C 0 The initial condition is C
0 at t 0
7
SolubilityHenrys Law constant
  • The solubility of a gas in a liquid solvent may
    be represented to good accuracy at dilute
    concentrations of the dissolved gas by Henry's
    Law
  • f H X
  • where f is the fugacity of the gas in the gas
    phase in equilibrium with the liquid phase of
    concentration X of dissolved gas.
  • H is the Henrys law constant, which is a
    function of temperature.
  • Thus, by measuring the solubility one can obtain
    an estimate of the Henry's law constant.

8
  • n gram moles of carbon dioxide absorbed in
    the liquid phase
  • PT corrected barometer reading
  • vapor pressure of Stoddard Solvent at cell
    temperature
  • Tp temperature at the pump
  • Tc temperature of the cell (bath
    temperature)
  • total gas volume delivered from the pump to
    the cell
  • Vcg volume of the gas phase in the cell
  • Zp compressibility factor of CO2 at pump T
    and PT
  • Zc compressibility factor of CO2 at cell T
    and PT
  • Vd dead volume in the system (cc)

9
  • The fugacity, f, can be determined from the Lewis
    and Randall Rule, which gives
  • f fugacity of CO2 in the gas phase
  • fo fugacity of pure gaseous CO2 at PT and cell
    T
  • y mole fraction of CO2 in gas phase
  • Thus
  • by definition
  • the fugacity coefficient for pure CO2 in the gas
    phase at cell T and P T

10
Heat of Mixing
  • Use Henrys Law coefficients at the three
    experimental temperatures to obtain the heat of
    mixing
  • Plotting ln(H) vs. 1/T gives a line with a slope
    of ?Hmix/R.
  • ?Hmix is expected to be negative, which would
    indicate that CO2 and Stoddard solvent are more
    energetically stable than apart (i.e., the
    interactions are favorable).

11
Experimental Cell Evacuation
12
Experimental Filling Syringe
13
Experimental Reduce to Atmospheric Pressure
14
Experimental Fill Cell
???????? between V4 and the cell is 40.5 cm and
the pipe diameter is 0.15 cm?
15
Penetration Model
16
References
  • Koretsky, Milo D. Engineering and Chemical
    Thermodynamics. John Wiley Sons, Inc., 2004.
  • Ophardt, Charles E. Virtual Chembook. Elmhurst
    College, 2003. Online Available at
    http//www.elmhurst.edu/chm/vchembook/174temppres
    .html
  • http//en.wikipedia.org/wiki/Lake_Nyos

17
Cell information
  • the dimension
  • Diameter 51.43 mm
  • Height of the lid 21.7 mm
  • Diameter to the lower section 50.4 mm
  • Depth of the lower section averaged 70.5 mm
  • Volume of the Stoddard liquid 100ml
  • Volume of the space (Gas) 104 ml
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