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General gravimetric calculations and the Gravimetric Factor

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Title: General gravimetric calculations and the Gravimetric Factor


1
Gravimetry
  • General gravimetric calculations and the
    Gravimetric Factor
  • Example Impure FeCO3 is converted to Fe2O3
    weighing 1.000 g. Whats the weight of FeCO3 in
    the original sample?
  • FeCO3 2H Fe2 CO2 H2O
  • Fe2 ?Br2 Fe3 Br-
  • Fe3 3OH- Fe(OH)3
  • Fe(OH)3 Fe2O3 3H2O
  • 2FeCO3 Fe2O3 2CO2

?
O
?
  • When the principal element or ion appears both in
    the numerator and denominator, determining the
    gravimetric factor is straight forward.

2
Gravimetry
  • General gravimetric calculations and the
    Gravimetric Factor
  • Sometimes things are somewhat more complicated!
  • Example What mass of CuI must have produced
    1.000 g Cu?
  • CuI 1e- Cu I-
  • CuI Cu2 I- 1e-
  • 2CuI Cu Cu2

3
Gravimetry
  • General gravimetric calculations and the
    Gravimetric Factor
  • Sometimes things are somewhat more complicated!
  • Example Br2 is determined by reducing the Br2 to
    Br-, precipitating the Br- with Ag, and
    converting the AgBr to AgCl with Cl2. What mass
    of Br2 is equivalent to 1.000 g AgCl?
  • Br2 2Br-
  • Br- Ag AgBr
  • 2AgBr Cl2 2AgCl Br2
  • In this case a common element does not appear in
    the numerator and denominator

4
Gravimetry
  • General gravimetric calculations and the
    Gravimetric Factor
  • Determining wt of analyte from gravimetric data
  • Example If 2.000g impure NaCl is dissolved in
    H2O and excess AgNO3 yields 4.7280 g AgCl, what
    is the chloride in the sample?

5
Gravimetry
  • General gravimetric calculations and the
    Gravimetric Factor
  • Determining wt of analyte from gravimetric data
  • Example A 0.5000 g sample of impure magnetite
    (Fe3O4) is converted to Fe2O3 weighing 0.4110 g.
    What is the Fe3O4 in the original sample?
  • Some problems involve analysis for more than one
    analyte in a sample
  • See Example 5-7 and problems 5-37 - 5-40 in FAC7
  • For each analyte, an independent equation must be
    established.

6
Gravimetry
  • Precipitating Agents are
  • Specific if they react to form a precipitate with
    only one chemical species
  • Selective if they react to form a precipitate
    with a limited number of chemical species
  • Desirable properties of precipitates
  • Easily filtered, easily washed free of
    contaminants
  • Low solubility so that little is lost during
    handling
  • Non-reactive toward the atmosphere - H2O, CO2, O2
  • Of known composition after drying or ignition
  • The mechanism of precipitation is important in
    determining particle size
  • Von Weimarn definition of relative
    supersaturation helps explain

Q actual concentration of slightly soluble
compound S equilibrium solubility of slightly
soluble compound
7
Gravimetry
  • The mechanism of precipitation is important in
    determining particle size
  • During the initial stages of precipitate
    formation, when a solution of precipitating
    agent is added to a solution of analyte
  • A localized volume of high relative
    supersaturation occurs until solution is mixed
  • QgtgtS and relative supersaturation is high
  • Colloidal particles form
  • Diameters 10-6 - 10-4 mm
  • Larger than typical small molecules
  • Not large enough to overcome Brownian motion and
    settle from solution
  • Too small to be retained by most filtering media
  • In order to produce a filterable precipitate the
    particles must be much larger than colloidal
    dimensions

8
Gravimetry
  • There are two competing processes that occur when
    a solution of precipitating agent is added to a
    solution of analyte
  • Nucleation is the formation of colloidal sites
    upon which additional precipitate forms
  • Particle growth is the increase in particle size
    as additional precipitate builds up on
    nucleation sites

9
Gravimetry
The mechanism of precipitation
  • At high relative supersaturation formation of
    colloidal nucleation sites is preferred
  • At low relative supersaturation particle growth
    is preferred and crystalline precipitates form

10
Gravimetry
  • The mechanism of precipitation
  • It is sometimes impossible to avoid formation of
    colloids
  • Substances that have very low solubilities are
    formed under conditions of high relative
    supersaturation
  • Sulfides, hydroxides, many precipitates of Ag
  • Stability of Colloidal precipitates
  • Results from adsorption of ions to the colloidal
    particles
  • The primary adsorption layer is the layer of
    adsorbed ions directly attached to the colloidal
    particle
  • Fajans rule the ion in the primary adsorption
    layer on an ionic colloidal particle will be the
    common ion of the substance in higher
    concentration in the mother liquor from which
    the colloid is formed.
  • Example Formation of AgCl by adding AgNO3 to a
    solution of NaCl
  • The AgCl formed initially will be in contact with
    a solution having excess Cl-
  • Cl- will be the primary adsorbed ion
  • Na will be in the secondary adsorption layer
  • In excess Ag, Ag will be adsorbed and NO3- is
    secondary ion
  • This electrical double layer produces a particle
    that is charged
  • Electrostatic repulsion between charged colloidal
    particles prevents agglomeration and formation
    of larger particles that can precipitate

11
Gravimetry
  • The mechanism of precipitation
  • Coagulating colloidal particles to form
    filterable precipitates
  • Heating with stirring
  • Reduces adsorption thus the charge of colloidal
    particles
  • Gives colloidal particles more kinetic energy -
    collisions between particles will be more
    effective in overcoming repulsions
  • Add inert electrolyte such as HNO3
  • Causes shrinkage of counter ion layer by
    increasing the concentration of ions of opposite
    charge to the primary adsorbed ions near the
    colloidal particle
  • Produces an insulating effect reducing the
    electrostatic repulsion between colloidal
    particles
  • Peptization is the resuspension of a colloidal
    precipitate by washing

12
Gravimetry
  • Impurities associated with colloidal precipitates
  • Coprecipitation is the contamination by an
    otherwise soluble component during formation of
    a precipitate
  • This is not contamination with another
    precipitate that happens to form
  • For colloidal precipitates coprecipitation
    involves adsorption of impurity ions
  • If AgCl is in contact with a solution containing
    excess Ag, Ag will be adsorbed along with
    counter ions such as NO3-
  • The surface area of colloidal precipitates is
    enormous 3 000 ft2/g!
  • Washing with water will not remove the adsorbate
    - it will peptize

13
Gravimetry
  • Impurities associated with colloidal precipitates
  • Producing a pure colloidal precipitate
  • Form the precipitate from a hot, stirred solution
    to which an appropriate electrolyte has been
    added to aid agglomeration
  • Digest the samples after precipitation - allow
    the precipitate to sit in contact with the
    precipitating agent while hot
  • This will remove weakly adsorbed water from the
    precipitate and produce a more dense, easier to
    filter precipitate
  • Filter the precipitate from hot solution
  • Wash with an electrolyte that produces a volatile
    adsorbate
  • Precipitation of Cl- by Ag has Ag as the
    primary adsorption ion
  • Washing with dilute HNO3 can exchange Ag with H
    and put NO- in the secondary adsorption layer
  • Heating to 110 oC will decompose the HNO3 to
    NO2(g) and NO(g)
  • Reprecipitate the compound which will minimize
    adsorption because there will be a lower
    concentration of adsorbing ions
  • For AgCl, redisolve using dilute NH3 - Ag(NH3)2
    is formed - and destroy the complex with HNO3
  • If possible form the precipitate by using
    homogeneous formation of the precipitating
    agent
  • OH- can be formed from hydrolysis of urea

Equations for formation of other precipitating
agents are shown in Table 5-3, p. 92 in FAC7.
14
Gravimetry
  • Formation of crystalline precipitates
  • Crystalline precipitate formation is preferred at
    low relative supersaturations
  • Keep Q small
  • Use dilute solution of of precipitating agent
  • Use small increments of precipitating solution
  • Use slow addition of precipitating solution with
    stirring
  • Keep S large
  • Keep the solution hot during the precipitation
    process

15
Gravimetry
  • Impurities associated with crystalline
    precipitates
  • Specific surface area of crystalline precipitates
    is small
  • Little interference from adsorption
  • Inclusion is the random distribution of impurity
    ions throughout the volume of the crystals
  • Isomorphic inclusion involves including ions that
    are the right size to fit in the crystal lattice
    and thus replace ions that should be there
  • No strain is imposed on the crystal
  • Nonisomorphic inclusion involves including ions
    that do not fit in the lattice as a result of
    the too rapid growth of the crystal
  • Occlusion involves trapping droplets of solution
    containing dissolved impurities in pockets of
    the growing crystal
  • Occlusion can also result from mechanical
    entrapment where two crystals come together and
    fuse as they grow

16
Gravimetry
  • Formation of crystalline precipitates
  • Purifying crystalline precipitates
  • Washing will not remove included or occluded
    impurities
  • Digestion is the best method of improving the
    purity and quality of a crystalline precipitate
  • Heat the precipitate in contact with its mother
    liquor
  • The crystals undergo dynamic dissolution and
    reformation
  • Trapped impurities are released and will be less
    likely to be trapped during the slow reformation
    of the precipitate
  • The reformed crystals are usually larger because
    of bridging between multiple crystals and are
    easier to filter

17
Gravimetry
  • Direction of Coprecipitation errors
  • Positive errors always occur if the contaminant
    is not a compound of the analyte
  • Contamination of Al(OH)3 with Fe3 increases the
    mass of precipitate over that expected if the
    precipitate were assumed to be pure Al(OH)3
  • Positive or negative errors can occur if the
    contaminant is a compound of the analyte
  • Contamination of Fe(OH)3 (molar mass107) by
    FeCl3 (molar mass162) gives a positive error
    since the mass of the precipitate is more than
    would be expected given the mass of Fe3 in the
    sample
  • Contamination of Fe(OH)3 (molar mass107) with
    Fe(OH)2 (molar mass89) gives a negative error
    since the mass of the precipitate is less than
    would be expected given the mass of Fe3 present
    in the sample

18
Gravimetry
  • Heating and Ignition of precipitates
  • Filtered precipitates normally are heated or
    ignited to produce a constant weight of
    precipitate
  • Heating precipitates usually removes water and
    other volatile components
  • Some precipitates (AgCl) can be brought to
    constant weight at 110 oC
  • Others require heating at considerably higher
    temperature - Ignition
  • BaSO4 requires heating to above 700 oC
  • Al2O3 requires heating above 1000 oC
  • CaC2O4 undergoes chemical reaction at various
    temperatures
  • 110 oC CaC2O4H2O is formed
  • 225 oC CaC2O4 is formed
  • 450 oC CaC2O4 CaCO3 CO

19
Gravimetry
  • Applications of Gravimetric Methods
  • Inorganic preciptating agents see Table 5-4, p.
    94 FAC7.
  • Reducing agents see Table 5-5, p 94, FAC7
  • Organic preciptating agents see p. 94-96, FAC7
  • Organic functional group analysis see Table 5-6,
    p. 96, FAC7
  • Volatilization methods see p. 96-96, FAC7
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