Download Chem 5336 (Introduction)

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

Document related concepts
Transcript
Introduction to
Electroanalytical Chemistry
Potentiometry, Voltammetry,
Amperometry, Biosensors
Applications
• Study Redox Chemistry
– electron transfer reactions, oxidation,
reduction, organics & inorganics, proteins
– Adsorption of species at interfaces
• Electrochemical analysis
– Measure the Potential of reaction or process
E = const + k log C (potentiometry)
– Measure the Rate of a redox reaction; Current
(I) = k C (voltammetry)
• Electrochemical Synthesis
Organics, inorganics, materials, polymers
Electrochemical Cells
• Galvanic Cells and Electrolytic Cells
• Galvanic Cells – power output; batteries
• Potentiometric cells (I=0) read Chapter 2
– measure potential for analyte to react
– current = 0 (reaction is not allowed to occur)
– Equil. Voltage is measured (Eeq)
• Electrolytic cells, power applied, output meas.
– The Nernst Equation
• For a reversible process: Ox + ne- → Red
• E = Eo – (2.303RT/nF) Log (ared/aox)
• a (activity), related directly to concentration
Voltammetry is a dynamic
method
Related to rate of reaction at an electrode
O + ne = R,
Eo in Volts
I = kA[O]
k = const. A = area
Faradaic current, caused by electron transfer
Also a non-faradaic current forms
part of background current
Electrical Double layer at Electrode
• Heterogeneous system: electrode/solution
interface
• The Electrical Double Layer, e’s in electrode;
ions in solution – important for voltammetry:
– Compact inner layer: do to d1, E decreases linearly.
– Diffuse layer: d1 to d2, E decreases exponentially.
Electrolysis: Faradaic and Non-Faradaic
Currents
• Two types of processes at electrode/solution
interface that produce current
– Direct transfer of electrons, oxidation or reduction
• Faradaic Processes. Chemical reaction rate at
electrode proportional to the Faradaic current.
– Nonfaradaic current: due to change in double layer
when E is changed; not useful for analysis
• Mass Transport: continuously brings reactant from the
bulk of solution to electrode surface to be oxidized or
reduced (Faradaic)
– Convection: stirring or flowing solution
– Migration: electrostatic attraction of ion to electrode
– Diffusion: due to concentration gradient.
Typical 3-electrode
Voltammetry cell
Reference electrode
Counter
electrode
Working electrode
O
e-
O
Mass transport
R
End of Working electrode
R
Bulk solution
Reduction at electrode
Causes current flow in
External circuit
Analytical Electrolytic Cells
• Use external potential (voltage) to drive
reaction
• Applied potential controls electron energy
• As Eo gets more negative, need more
energetic electrons in order to cause
reduction. For a reversible reaction:
–  Eapplied is more negative than Eo, reduction
will occur
– if Eapplied is more positive than Eo, oxidation
will occur
O + ne- = R Eo,V electrode reaction
• Current Flows in electrolytic cells
– Due to Oxidation or reduction
– Electrons transferred
– Measured current (proportional to reaction
rate, concentration)
• Where does the reaction take place?
– On electrode surface, soln. interface
– NOT in bulk solution
Analytical Applications of Electrolytic Cells
• Amperometry
– Set Eapplied so that desired reaction occurs
– Stir solution
– Measure Current
• Voltammetry
– Quiet or stirred solution
– Vary (“scan”) Eapplied
– Measure Current
• Indicates reaction rate
• Reaction at electrode surface produces concentration
gradient with bulk solution
• Mass transport brings unreacted species to electrode surface
Cell for voltammetry, measures I vs. E
wire
potentiostat
insulator
electrode
material
reference
N2
inlet
counter
working electrode
Electrochemical cell
Output, I vs. E, quiet solution
Input: E-t waveform
E, V
time
reduction
Polarization - theoretical
Ideal Non-Polarized Electrode
Ideally Polarized Electrode
reduction
No oxidation or reduction
oxidation
Possible STEPS in electron transfer processes
Charge-transfer may be rate limiting
Rate limiting step may be mass transfer
Rate limiting step may be chemical reaction
Adsorption, desorption or crystallization polarization
Overvoltage or Overpotential η
• η = E – Eeq; can be zero or finite
– E < Eeq  η < 0
– Amt. of potential in excess of Eeq needed to make
a non-reversible reaction happen, for example
reduction
Eeq
NERNST Equation: Fundamental Equation
for reversible electron transfer at electrodes
O + ne- = R,
Eo in Volts
•E.g., Fe3+ + e- = Fe2+
If in a cell, I = 0, then E = Eeq
All equilibrium electrochemical reactions obey the
Nernst Equation
Reversibility means that O and R are at equilibrium at all times, not all
Electrochemical reactions are reversible
E = Eo - [RT/nF] ln (aR/aO)
aR = fRCR
ao = foCo
;
a = activity
f = activity coefficient, depends on ionic strength
Then E = Eo - [RT/nF] ln (fR/fO) - [RT/nF] ln (CR/CO)
F = Faraday const., 96,500 coul/e, R = gas const.
T = absolute temperature
Ionic strength I = Σ zi2mi,
Z = charge on ion, m = concentration of ion
Debye Huckel theory says log fR = 0.5 zi2 I1/2
So fR/fOwill be constant at constant I.
And so, below are more usable forms of Nernst Eqn.
E = Eo - const. - [RT/nF] ln (CR/CO)
Or
E = Eo’ - [RT/nF] ln (CR/CO); Eo’ = formal potential of O/R
At 25 oC using base 10 logs
E = Eo’ - [0.0592/n] log (CR/CO); equil. systems