What is the Difference Between Polarography and Voltammetry?
🆚 Go to Comparative Table 🆚Polarography and voltammetry are both electroanalytical methods used to analyze unknown substances in solution that are electroactive, or capable of generating an electric current when an electric potential is applied to them. Despite their similarities, there are key differences between the two techniques:
- Types of electrodes used: The main difference between polarography and voltammetry lies in the polarization electrode. Polarography uses a dropping mercury electrode (DME) or other liquid electrode whose surface can be renewed periodically, while voltammetry uses a liquid or solid electrode whose surface is still.
- Subclass relationship: Polarography is considered a subclass of voltammetry.
- Sensitivity: Polarography is known for its high sensitivity and ability to detect low concentrations, making it more suitable for the analysis of trace amounts of analytes in solution.
- Applications: Polarography is best suited for the analysis of electrochemically active species, while voltammetry can be used for both electroactive and non-electroactive species.
In summary, the key difference between polarography and voltammetry is the type of polarization electrode used. Polarography uses a liquid electrode with a renewable surface, while voltammetry uses a still surface electrode. Polarography is a more sensitive technique, making it better suited for the analysis of trace amounts of analytes in solution, whereas voltammetry can be used for a broader range of species.
Comparative Table: Polarography vs Voltammetry
Here is a table comparing the differences between polarography and voltammetry:
| Polarography | Voltammetry |
|---|---|
| A type of voltammetry that uses a liquid metal electrode | An analytical technique that measures the current as a function of the applied potential in an electrochemical cell |
| Involves the study of solutions of electrode processes by means of electrolysis | Applies a time-dependent potential to an electrochemical cell |
| Uses a dropping mercury electrode as the polarizable electrode | Requires at least two electrodes: a working electrode that makes contact with the analyte and applies the desired potential, and a second electrode with a known potential to gauge the potential of the working electrode |
| Has sigmoidal shapes due to linear sweep methods controlled by diffusion mass transport | Comes in various techniques, such as differential pulse voltammetry, which requires a minimum separation of ±0.04–0.05 V between half-wave potentials or peak potentials for two analytes |
Polarography is a subclass of voltammetry, and the key difference between the two is the type of electrode used and the specific techniques employed.
- Potentiometry vs Amperometry
- Polarizable vs Non Polarizable Electrode
- Anodic vs Cathodic Polarization
- Voltmeter vs Ammeter
- Voltmeter vs Multimeter
- Polarimeter vs Refractometer
- Electrophoresis vs Chromatography
- Ionization vs Electrolysis
- Electrophoretic Deposition vs Electrodeposition
- Electrophoresis vs Dielectrophoresis
- Electroplating vs Electrolysis
- Volumetric vs Potentiometric Titration
- Electrophoresis vs Electroosmosis
- Capillary Electrophoresis vs Gel Electrophoresis
- Photocatalysis vs Electrocatalysis
- Electrolyte vs Electrolysis
- pH Meter vs Conductivity Meter
- Potential Difference vs Voltage
- Potentiometric vs Conductometric Titrations