Conductivity cell
{{Short description|Solution's conductivity meter}}
{{About|tool that measures the aqueous solution conductivity|Other tool|Electrical conductivity meter}}
In electrochemistry, conductivity cell is crucial for measuring the solution's electrical conductivity. The concentration and ion mobility of solution in chemistry are related to conductivity of that solution. The conductive cells are useful for determining the ionic strength and the purity of solutions.{{Cite book |last=Sandhya |first=Mrs. |title=Pharmaceutical Analysis |date=2025-05-10 |publisher=JEC Publication |isbn=9789361751585 |page=155 |language=English}} File:Apparatus of conductivity meter.png
Conductivity cells are designed to work in variety of situations and measurement kinds. Conductivity cells come in variety of forms, including low and high conductivity cell types. In many cases the cells with cylindrical electrode typologies or parallel plate layouts are used.
Utility
Conductivity cell is used as a sensor or meter that detects the conductivity of the solution. The setup consist of two electrodes made of platinum or stainless steel and these electrodes are directly connected to the solution being analysed.{{Cite book |last=Ware |first=A. L. |title=A textbook of pharmaceutical analysis |publisher=Shaswant Publication |year=2024 |isbn=9789360877453 |edition=1rst |location=India |pages=166 |language=English}}
It is also used to make sure that the electrode and solution are in contact so enough that they can flawlessly conduct electricity. For accurate readings, temperature compensation is essential, since conductivity is sensitive to temperature variations. A resistance thermometer is embedded within the sample cell to detect the temperature. This reading is used to automatically adjust the measurement circuit, typically by modifying the zero level or the amplification range, so the output reflects only changes in chemical concentration and not temperature shifts.
Setup
In the physical setup, the cell is compact with a large electrode surface area to reduce the influence of fouling and to ensure stability. It includes insulated and grounded components to maintain measurement integrity. The entire assembly is cast or sealed to prevent leaks, especially when dealing with corrosive or radioactive solutions.{{Cite journal |last=Colvin |first=D. W. |title=An in-line conductivity meter with temperature compensation |journal=AEC Research and Development Report |volume=1rst |pages=8–11 |via=Google Books}}
The system is calibrated using standard solutions of known conductivity at a reference temperature. Once calibrated, the unit continuously measures conductance in-line without the need for manual sampling. The output can be fed to a recorder or control system, giving real-time feedback on concentration changes in a process stream. The mechanism for temperature compensation is driven by a potentiometric adjustment linked to the recorder, ensuring that as temperature changes are detected, they immediately adjust the baseline of the conductance reading.
This makes the conductivity cell a practical tool for process control in chemical systems where rapid and continuous monitoring is necessary.
Types of conductivity cell
= Electrodeless C cell =
This type of conductivity cell uses electromagnetic waves to measure the conductivity of a solution, meaning it does not have any kind of electrodes that are attached to solution. It does this measurement by releasing some electromagnetic field and these electromagnetic field change based on conductivity of solution allowing the measurement.
= Electrode based conductivity cell =
This is a traditional kind of conductivity which uses the electrodes and measures in the setup explained above.{{Cite web |title=Understanding Conductivity Cells: Basics & Applications |url=https://pharmacyinfoline.com/conductivity-cell/ |access-date=2025-05-12 |website=Pharmacy Infoline |language=en-US}}
Mathematical measurement
- Conductivity cell: The cell constant is a characteristic of a conductivity cell, defined by the geometry of the electrodes and the distance between them. It is calculated using the formula:{{Cite web |date=2025-03-01 |title=Conductivity Sensor Cell Constant: Comprehensive Guide to Precise Electrical Measurement - sensor.wiki |url=https://sensor.wiki/conductivity-sensor-cell-constant/ |access-date=2025-05-12 |language=en-US}}{{Cite web |last=O'Donnell |first=Dominic |date=2017-11-29 |title=Understanding Conductivity Cell Constants {{!}} Sensorex |url=https://sensorex.com/conductivity-cell-constants/ |access-date=2025-05-12 |website=Sensorex Liquid Analysis Technology |language=en-US}}
2. Conductivity is determined by the product of the conductance and the cell constant:{{Cite web |title=Application of Conductivity |url=https://www.emerson.com/documents/automation/application-data-sheet-theory-application-of-conductivity-rosemount-en-68442.pdf |archive-url=http://web.archive.org/web/20240601141817/https://www.emerson.com/documents/automation/application-data-sheet-theory-application-of-conductivity-rosemount-en-68442.pdf |archive-date=2024-06-01 |access-date=2025-05-12 |website=www.emerson.com}}{{Cite web |title=Conductivity theory and measurement |url=https://iccontrols.com/wp-content/uploads/art-4-1_conductivity_theory_and_measurement.pdf}}
[ G= conductance and K = cell constant]
3. Conductance is the reciprocal of resistance.{{Cite web |title=Cell Constant given Conductance and Conductivity Calculator {{!}} Calculate Cell Constant given Conductance and Conductivity |url=https://www.calculatoratoz.com/en/cell-constant-if-conductance-and-conductivity-given-calculator/Calc-18672 |access-date=2025-05-12 |website=www.calculatoratoz.com |language=en}} It is the direct measurement of the strength (or ability) of an solution to conduct electricity:
4. Calibration method: To determine the cell constant, a standard solution with known conductivity is used. Measure the resistance of this solution with the conductivity cell, then calculate the cell constant{{Cite web |title=Calibration method of conductivity cells |url=https://www.oiml.org/en/files/pdf_r/r068-e85.pdf}}-: