User:Cemes4/Voltammetry

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Article Draft

Summary Notes from peer review to consider:

• Add more figures/ captions to current ones
• Check citation formatting
• Put types of voltammetry and definitions into a table (improve clarity)
• Add equations
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• Condense some of the sentences (brogan)
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Theory [edit]

Voltammetry is the study of current as a function of applied potential. Voltammetric methods involve electrochemical cells, and investigate the reactions occurring at electrode/electrolyte interfaces.^[1] The reactivity of analytes in these half-cells is used to determine their concentration. It is considered a dynamic electrochemical method as the applied potential is varied over time and the corresponding changes in current are measured.^[1] Most experiments control the potential (volts) of an electrode in contact with the analyte while measuring the resulting current (amperes).

Electrochemical Cells

Electrochemical cells are used in voltammetric experiments to drive the redox reaction of the analyte. Like other electrochemical cells, two half-cells are required, one to facilitate reduction and the other oxidation. The cell consists of an analyte solution, an ionic electrolyte, and two or three electrodes, with oxidation and reduction reactions occurring at the electrode/electrolyte interfaces.^[2] As a species is oxidized, the electrons produced pass through an external electric circuit and generate a current, acting as an electron source for reduction. The generated currents are Faradaic currents, which follow Faraday’s law. As Faraday’s law states that the” number of moles of a substance, m, produced or consumed during an electrode process is proportional to the electric charge passed through the electron” the faradaic currents allow analyte concentrations to be determined.^[3] Whether the analyte is reduced or oxidized depends on the analyte, but its reaction always occurs at the working/indicator electrode. Therefore, the working electrode potential varies as a function of the analyte concentration. A second auxiliary electrode completes the electric circuit. A third reference electrode provides a constant, baseline potential reading for the other two electrode potentials to be compared to.

Three Electrode System

- Copy over from original wikipedia page

Voltammograms

A voltammogram is a graph that measures the current of an electrochemical cell as a function of the potential applied.^[4] This graph is used to determine the concentration and the standard potential of the analyte. To determine the concentration, values such as the limiting or peak current are read from the graph and applied to various mathematical models.^[1] After determining the concentration, the applied standard potential can be identified using the Nernst equation.^[1]

There are three main shapes for voltammograms. The first shape is dependent on the diffusion layer.^[5] If the analyte is continuously stirred, the diffusion later will be a constant width and produce a voltammogram that reaches a constant current. The graph takes this shape as the current increases from the background residual to reach the limiting current (il). If the mixture is not stirred, the width of the diffusion layer eventually increases. This can be observed by the maximum peak current (ip), and is identified by the highest point on the graph. The third common shape for a voltammogram measures the sample for change in current rather than current applied. A maximum current is still observed, but represents the maximum change in current.^[1]

 

A common shape for current vs potential voltammogram measuring limiting peak current

 

A common voltammogram shape showing change in current vs potential

 

A common shape for current vs potential voltammogram measuring maximum peak current

Mathematical Models

To determine analyte concentrations, mathematical models are required to link the applied potential and current measured over time. The Nernst equation relates electrochemical cell potential to the concentration ratio of the reduced and oxidized species in a logarithmic relationship.^[3] The Nernst equation is as follows:

${\displaystyle E=E^{0}-{\frac {RT}{zF}}\ln Q}$ 

Where:

• ${\displaystyle E}$  Reduction potential
• ${\displaystyle E^{0}}$ : standard potential
• ${\displaystyle R}$ : universal gas constant
• ${\displaystyle T}$ : temperature in kelvin
• ${\displaystyle z}$ : ion charge (moles of electrons)
• ${\displaystyle F}$ : Faraday constant
• ${\displaystyle Q}$ : Reaction quotient

This equation describes how the changes in applied potential will alter the concentration ratio. However, the Nernst equation is limited, as it is modeled without a time component and voltammetric experiments vary applied potential as a function of time. Other mathematical models, primarily the Butler-Volmer equation, the Tafel equation, and Fick’s law address the time dependence.

The Butler–Volmer equation relates concentration, potential, and current as a function of time.^[2] It describes the non-linear relationship between the electrode and electrolyte voltage difference and the electrical current. It helps make predictions about the how the forward and backward redox reactions affect potential and influence the reactivity of the cell.^[6] This function includes a rate constant which accounts for the kinetics of the reaction. A compact version of the Butler-Volmer equation is as follows:

${\displaystyle {\displaystyle j=j_{0}\cdot \left\{\exp \left[{\frac {\alpha _{\rm {a}}zF\eta }{RT}}\right]-\exp \left[-{\frac {\alpha _{\rm {c}}zF\eta }{RT}}\right]\right\}}}$ 

Where:

• ${\displaystyle j}$ : electrode current density, A/m² (defined as j = I/S)
• ${\displaystyle j_{0}}$ : exchange current density, A/m²
• ${\displaystyle E}$ : electrode potential, V
• ${\displaystyle {\displaystyle E_{\rm {eq}}}}$ : equilibrium potential, V
• ${\displaystyle T}$ : absolute temperature, K
• ${\displaystyle z}$ : number of electrons involved in the electrode reaction
• ${\displaystyle F}$ : Faraday constant
• ${\displaystyle R}$ : universal gas constant
• ${\displaystyle \alpha _{c}}$ : so-called cathodic charge transfer coefficient, dimensionless
• ${\displaystyle \alpha _{a}}$ : so-called anodic charge transfer coefficient, dimensionless
• ${\displaystyle \eta }$ : activation overpotential (defined as ${\displaystyle {\displaystyle \eta =E-E_{\rm {eq}}}}$ ).

At high overpotentials, the Butler–Volmer equation simplifies to the Tafel equation. The Tafel equation relates the electrochemical currents to the overpotential exponentially, and is used to calculate the reaction rate.^[6] The overpotential is calculated at each electrode separately, and related to the voltammogram data to determine reaction rates. The Tafel equation for a single electrode is:

${\displaystyle {\displaystyle \eta =\pm A\cdot \log _{10}\left({\frac {i}{i_{0}}}\right)}}$ 

Where:

• the plus sign under the exponent refers to an anodic reaction, and a minus sign to a cathodic reaction
• ${\displaystyle \eta }$ : overpotential, V
• A: "Tafel slope", V
• ${\displaystyle i}$ : current density, A/m²
• ${\displaystyle i_{0}}$ : "exchange current density", A/m².

As the redox species are oxidized and reduced at the electrodes, material accumulates at the electrode/electrolyte interface.^[2] Material accumulation creates a concentration gradient between the interface and the bulk solution. Fick's laws of diffusion is used to relate the diffusion of oxidized and reduced species to the faradaic current used to describe redox processes. Fick's law is most commonly written in terms of moles, and is as follows:

${\displaystyle {\displaystyle J=-D{\frac {d\varphi }{dx}}}}$ 

Where:

• J: diffusion flux (in amount of substance per unit area per unit time)
• D: diffusion coefficient or diffusivity. (in area per unit time)
• φ: concentration (in amount of substance per unit volume)
• x: position (in length)

Types of voltammetry[edit]

Type of voltammetry	Description
Linear sweep voltammetry	Any voltammetric method where the potential at the working electrode is swept linearly with time, the reference electrode potential remains constant, and measurements are taken of the current at the working electrode.[7]
Staircase voltammetry	A specialized linear sweep voltammetry technique where voltage is applied for a duration, followed by measurement of current, then repeated for a varying voltages using a staircase program.[6]
Squarewave voltammetry	Electrochemical method that combines aspects of many pulse voltammetry methods. SWV has a similar waveform to that of DPV but waveform is analyzed as a staircase scan for result interpretation.[6]
Cyclic voltammetry	A voltammetric method that can be used to determine diffusion coefficients and half cell reduction potentials.[8]
Anodic stripping voltammetry	A quantitative, analytical method for trace analysis of metal cations. The analyte is deposited (electroplated) onto the working electrode during a deposition step, and then oxidized during the stripping step. The current is measured during the stripping step.[9]
Cathodic stripping voltammetry	A quantitative, analytical method for trace analysis of anions. A positive potential is applied, oxidizing the mercury electrode and forming insoluble precipitates of the anions. A negative potential then reduces (strips) the deposited film into solution.[10]
Adsorptive stripping voltammetry	A quantitative, analytical method for trace analysis. The analyte is deposited simply by adsorption on the electrode surface (i.e., no electrolysis), then electrolyzed to give the analytical signal. Chemically modified electrodes are often used.[11]
Alternating current voltammetry	A type of cyclic voltammetry where small sinusoidal oscillations in voltage are applied to an electrochemical cell while varying the overall voltage.[12]
Polarography	a subclass of voltammetry where the working electrode is a dropping mercury electrode (DME), useful for its wide cathodic range and renewable surface.[13]
Rotated electrode voltammetry	A hydrodynamic technique in which the working electrode, usually a rotating disk electrode (RDE) or rotating ring-disk electrode (RRDE), is rotated at a very high rate. This technique is useful for studying the kinetics and electrochemical reaction mechanism for a half reaction.[14]
Normal pulse polarography	An electrochemical technique where the potential is started at the same value for each step and amplitude is increased for each subsequent step. Measurements of current are taken as function of time and potential between the indicator and reference electrodes. [15][16]
Normal pulse voltammetry	An electrochemical technique that uses the same waveform as normal pulse polarography, but can be used to refer to waveforms of non-polarographic electrodes.[17]
Differential pulse voltammetry	An electrochemical technique similar to normal pulse voltammetry but the applied base potential is increased or decreased steadily, and the pulse height: base height ratio is kept constant. In DPV, measurements of current are taken twice during each drop, first immediately before the pulse and second before the drop is dislodged.[6]
Chronoamperometry	An electrochemical experiment type where potential is varied at the working electrode and current is recorded as a function of time.[6]

References

1. Harvey, David (2000). Modern analytical chemistry. Boston: McGraw-Hill. ISBN 0-07-237547-7. OCLC 41070677.
2. Kounaves, S.P., 1997. Voltammetric techniques. Handbook of instrumental techniques for analytical chemistry, pp.709-726.
3. Scholz, Fritz (2015-12). "Voltammetric techniques of analysis: the essentials". ChemTexts. 1 (4): 17. doi:10.1007/s40828-015-0016-y. ISSN 2199-3793. {{cite journal}}: Check date values in: |date= (help)
4. "voltammogram | instrument | Britannica". www.britannica.com. Retrieved 2022-10-24.
5. Laboratory techniques in electroanalytical chemistry. Peter T. Kissinger, William R. Heineman (2nd ed., rev. and expanded ed.). New York: Marcel Dekker, Inc. 1996. ISBN 0-8247-9445-1. OCLC 33359917.
6. Bard, Allen J. (2001). Electrochemical methods : fundamentals and applications. Larry R. Faulkner (2nd ed.). Hoboken, NJ. ISBN 0-471-04372-9. OCLC 43859504.
7. Skoog, Douglas A. (2018). Principles of instrumental analysis. F. James Holler, Stanley R. Crouch (7th ed.). Australia. ISBN 978-1-305-57721-3. OCLC 986919158.
8. "11.4: Voltammetric Methods". Chemistry LibreTexts. 2016-12-24. Retrieved 2022-11-09.
9. Thomas, F. G. (2001). Introduction to voltammetric analysis : theory and practice. Günter Henze. Collingwood, Vic.: CSIRO Pub. ISBN 978-0-643-06593-2. OCLC 711261475.
10. Achterberg, E.P.; Barriada, J.L.; Braungardt, C.B. (2005), "VOLTAMMETRY | Cathodic Stripping", Encyclopedia of Analytical Science, Elsevier, pp. 203–211, doi:10.1016/b0-12-369397-7/00649-x, ISBN 978-0-12-369397-6, retrieved 2022-11-09
11. 1948-, Wang, Joseph, (1985). Stripping analysis : principles, instrumentation, and applications. VCH. ISBN 0-89573-143-6. OCLC 299394898. {{cite book}}: |last= has numeric name (help)
12. Administrator (2013-11-14). "AC Cyclic Voltammetry". www.ceb.cam.ac.uk. Retrieved 2022-10-22.
13. Reinmuth, W. H. (1961-11-01). "Theory of Stationary Electrode Polarography". Analytical Chemistry. 33 (12): 1793–1794. doi:10.1021/ac60180a004. ISSN 0003-2700.
14. Holze, Rudolf (2002-02-15). <655::aid-anie655>3.0.co;2-i "Book Review: Electrochemical Methods. Fundamentals and Applications (2nd Edition). By Allen J. Bard and Larry R. Faulkner". Angewandte Chemie International Edition. 41 (4): 655–657. doi:10.1002/1521-3773(20020215)41:4<655::aid-anie655>3.0.co;2-i. ISSN 1433-7851.
15. "Ontology". www.rsc.org. Retrieved 2022-10-23.
16. "Definition of normal_pulse_polarography_npp - Chemistry Dictionary". www.chemicool.com. Retrieved 2022-10-23.
17. "Normal Pulse Voltammetry (NPV)". Pine Research Instrumentation Store. 2019-03-06. Retrieved 2022-10-23.