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Voltammetry

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Electrochemistry techniques based on current (i) measurement as function of voltage (Eappl) Working electrode (microelectrode) place where redox occurs – PowerPoint PPT presentation

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Title: Voltammetry


1
Voltammetry
  • Electrochemistry techniques based on current (i)
    measurement as function of voltage (Eappl)
  • Working electrode
  • (microelectrode) place where redox occurs
  • surface area few mm2 to limit current flow
  • Reference electrode
  • constant potential reference (SCE)
  • Counter electrode
  • inert material (Hg, Pt)
  • plays no part in redox but completes circuit
  • Supporting electrolyte
  • alkali metal salt does not react with electrodes
    but has conductivity

2
Voltammetry
  • Potentiostat (voltage source) drives cell
  • supplies whatever voltage needed between working
    and counter electrodes to maintain specific
    voltage between working and reference electrode
  • Almost all current carried between working and
    counter electrodes
  • Voltage measured between working and reference
    electrodes
  • Analyte dissolved in cell not at electrode
    surface

3
Method
  • Excitation signal applied
  • Wave response based on method
  • Linear
  • Differential pulse
  • Square wave
  • Cyclic
  • Developed current recorded

4
Signals
5
Electrodes
6
Potential ranges
  • Number of useful elements for electrodes
  • Pt
  • Hg
  • C
  • Au
  • Limits
  • Oxidation of water
  • 2H2O-gt4H O2(g) 4e-
  • Reduction of water
  • 2H2O 2e- -gtH2 2OH-

7
Overpotential
  • Overpotential h always reduces theoretical cell
    potential when current is flowing
  • h Ecurrent - Eequilibrium
  • Overpotential due to electrode polarization
  • concentration polarization - mass transport
    limited
  • adsorption/desorption polarization - rate of
    surface attach/detachment
  • charge-transfer polarization - rate of redox
    reaction
  • reaction polarization - rate of redox reaction of
    intermediate in redox reaction
  • Overpotential means must apply greater potential
    before redox chemistry occurs

8
Voltammograms
  • Current against applied voltage
  • Increase in current at potential at which analyte
    is reduced
  • Reaction requires electrons
  • supplied by potentiostat
  • Half wave potential (E1/2) is close to E0 for
    reduction reaction
  • Limiting current proportional to analyte activity

9
Methods
  • Current is just measure of rate at which species
    can be brought to electrode surface
  • Stirred - hydrodynamic voltammetry
  • Nernst layer near electrode
  • Diffusion layer
  • Migration
  • convection

10
Methods
  • Analyte (A) and product (P)
  • In stirred solution convection dominates

11
Methods
  • Current is a measure of how fast the analyte can
    go to electrode surface

12
Hydrodynamic
  • Single voltammogram can quantitatively record
    many species
  • Requires sufficient separation of potentials
  • Need to remove O2

13
Hanging Hg electrodePolarography
  • Differs from hydrodynamic
  • unstirred (diffusion dominates)
  • dropping Hg electrode (DME) is used as working
    electrode
  • current varies as drop grows then falls off

14
Linear Scan
  • Advantages of DME
  • clean surface and constant mixing
  • constant current during drop growth
  • No H2 formation
  • Disadvantages of DME
  • Hg easily oxidized
  • cumbersome to use

15
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16
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17
Cyclic Voltammetry
  • Oxidation and reduction
  • Variation of rates
  • Peak potentials
  • Anode (bottom peak)
  • Cathode (top peak)
  • Difference 0.0592/n
  • Peak currents
  • Cathode (line to peak)
  • Anode (slope to bottom)
  • Peak currents equal and opposite sign
  • Mechanisms and rates of redox

18
CV data
19
Molten Salt Processes
  • Inorganic phase solvent
  • High temperature needed to form liquid phase
  • Different inorganic salts can be used as solvents
  • Separations based on precipitation
  • Reduction to metal state
  • Precipitation
  • Two types of processes in nuclear technology
  • Fluoride salt fluid
  • Chloride eutectic
  • Limited radiation effects
  • Reduction by Li

20
Molten Salt Reactor
  • Fluoride salt
  • BeF2, 7LiF, ThF4, UF4 used as working fluid
  • thorium blanket
  • fuel
  • reactor coolant
  • reprocessing solvent
  • 233Pa extracted from salt by liquid Bi through
    Li based reduction
  • Removal of fission products by high 7Li
    concentration
  • U removal by addition of HF or F2

21
Pyroprocesses
  • Electrorefining
  • Reduction of metal ions to metallic state
  • Differences in free energy between metal ions and
    salt
  • Avoids problems associated with aqueous chemistry
  • Hydrolysis and chemical instability
  • Thermodynamic data at hand or easy to obtain
  • Sequential oxidation/reduction
  • Cations transported through salt and deposited on
    cathode
  • Deposition of ions depends upon redox potential

22
Electrochemical Separations
  • Selection of redox potential allows separations
  • Can use variety of electrodes for separation
  • Developed for IFR and proposed for ATW
  • Dissolution of fuel and deposition of U onto
    cathode
  • High temperature, thermodynamic dominate
  • Cs and Sr remain in salt, separated later

23
Electrorefining
Electrorefining
24
Reduction of oxide fuel
Step 2
  • Input
  • 445 kg oxide (from step 1)
  • 135 kg Ca
  • 1870 kg CaCl2
  • Output
  • 398 kg heavy metal (to step 3)
  • To step 8
  • 2 kg Cs, Sr, Ba
  • 189 kg CaO
  • 1870 kg CaCl2
  • 1 kg Xe, Kr to offgas

Metal
Operating Conditions T 1125 K, 8 hours 4 100
kg/1 PWR assembly
25
Uranium Separation
Step 3
  • Input
  • 398 kg heavy metal (from step 2)
  • 385 kg U, 20 kg U3(enriched, 6)
  • 3.98 kg TRU, 3.98 kg RE
  • 188 kg NaCl-KCl
  • Output
  • 392 kg U on cathode
  • To step 4 (anode)
  • 15 g TRU, 14 g RE, 2.8 kg U, 5 kg Noble Metal
  • Molten Salt to step 5
  • 10 kg U, 3.9 kg TRU,
  • 3.9 kg RE, 188 kg NaCl-KCl

Operating Conditions T 1000 K, I 500 A, 265
hours 4 100 kg/1 PWR assembly
26
Polishing Reduces TRU Discharge
Step 4
  • Input from Anode 3
  • 5 kg Noble Metal, 2.8 kg U, 15 g TRU, 14 g RE,
    1.1 kg U3, 18.8 kg NaCl-KCl
  • Output
  • Anode
  • 5 kg Noble Metal, 0.15 g U, 0.045 g TRU, 0.129 g
    RE
  • Cathode
  • 1.5 g Noble Metal, 2.9 kg U
  • Molten Salt (to 3)
  • 28 g Noble Metal, 1 kg U, 15 g TRU, 14 g RE, 18.8
    kg NaCl-KCl

Metal
Operating Conditions T 1000 K, I 500 A, 2
hours 1 PWR assembly
27
Electrowinning Provide Feed for Fuel
Step 5
  • Input from molten salt from 3
  • 10 kg U, 4 kg TRU, 4 kg RE, 4.3 kg Na as alloy,
    188 kg NaCl-KCl
  • Output
  • Cathode
  • U extraction 9.2 kg
  • U/TRU/RE extraction, 1 kg U, 4 kg TRU, 0.5 kg RE
  • Molten Salt (to 7)
  • 3.5 kg RE, 192 kg NaCl-KCl

Metal
Operating Conditions T 1000 K, I 500 A, 3.7
hours for U/TRU/RE, 6.2 hours for U 1 PWR assembly
28
Reduction of Rare Earths
Step 7
  • Input
  • Molten Salt from 5
  • 3.4 kg RE
  • 1.7 kg Na as alloy
  • 188 kg NaCl-KCl
  • Output
  • Molten Salt (to step 3)
  • 189 kg NaCl-KCl
  • Metal Phase
  • 3.4 kg RE

Metal
Operating Conditions T 1000 K, 8 hours
29
Recycle Salt Reduction of Oxide
Step 8
  • Input
  • Chlorination
  • 189 kg CaO, 1870 kg CaCl2, 239 kg Cl2
  • Electrowinning
  • 2244 kg CaCl2
  • Output
  • Chlorination
  • 2244 kg CaCl2, 54 kg O2
  • Electrowinning (to 2)
  • 1870 kg CaCl2, 135 kg
  • Ca, (239 kg Cl2)

Operating Conditions T 1000 K, I 2250 A, 80
hours
30
U, TRU, and Fission Product Separation
Step 10
  • Input
  • 45 kg from Step 9 (includes Zr)
  • Includes 9.5 kg TRU, 0.5 kg RE
  • Output
  • Anode
  • 33 kg NM, 2 kg U
  • Molten Salt (to 11)
  • Small amounts of U, TRU, RE
  • Cathode (to 12)
  • Most TRU, RE

Operating Conditions T 1000 K, I 500 A, 6.7
hours
31
Electrowinning TRU for Salt Recycle
Step 11
  • Input from molten salt from 10
  • 1.7 kg U, 7.4 kg TRU, 0.5 kg RE, 2.8 kg Na as
    alloy, 188 kg NaCl-KCl
  • Output
  • Cathode (to 12)
  • U/TRU/RE extraction, 1.7 kg U, 7.4 kg TRU, 0.1 kg
    RE
  • Molten Salt (to 13)
  • 0.4 kg RE, 191 kg NaCl-KCl

Metal
Operating Conditions T 1000 K, I 500 A,
6.1hours for U/TRU/RE Salt from 10
electrorefining systems
32
Reduction to Remove Rare Earths
Step 13
  • Input
  • 0.4 kg RE (from 11), 188 kg NaCl-KCl, 0.2 kg Na
    as alloy
  • Output
  • Molten Salt
  • 188 kg NaCl-KCl
  • Metal Phase
  • 0.4 kg RE

Metal
Operating Conditions T 1000 K, 8 hours
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