Chemistry:Mercury coulometer
In electrochemistry, a mercury coulometer is an analytical instrument which uses mercury to perform coulometry (determining the amount of matter transformed in a chemical reaction by measuring electric current) on the following reaction:[1][2][3] [math]\displaystyle{ \ce{Hg^2+} + \ce{2e^- \lt =\gt Hg^\circ} }[/math]
These oxidation/reduction processes have 100% efficiency with the wide range of the current densities.[citation needed] Measuring of the quantity of electricity (coulombs) is based on the changes of the mass of the mercury electrode. Mass of the electrode can be increased during cathodic deposition of the mercury ions or decreased during the anodic dissolution of the metal. [math]\displaystyle{ Q = \frac{ 2 \, \Delta m \, F}{M_\ce{Hg}}, }[/math] where Q is the quantity of electricity; Δm are the mass changes; F is the Faraday constant; and MHg is the molar mass of mercury.
Use as Hour Meter
Before the development of solid-state electronics, coulometers were used as long-period (up to 25,000 hours) elapsed hour meters in electronic equipment and other devices, including on the Apollo Program space vehicles. By passing a constant, calibrated current through the coulometer, the movement of a gap between mercury droplets provides a visual indication of elapsed time. [4][5] Brands included HP's Chronister and Curtis' Indachron.
Construction
This coulometer has different constructions but all of them are based on mass measurements. The device consists of two reservoirs connected by a thin graduated capillary tube containing a solution of the mercury(II)-ions. Each of the reservoirs has an electrode immersed in a drop of mercury. Another small drop of mercury is inserted into the capillary. When the current is turned on, it initiates dissolution of the metallic mercury on one side of the drop in the capillary and deposition on the other side of the same drop. This drop starts to move. Because of the high efficiency of the deposition/dissolution of the mercury under the current influence, the mass or volume of this small drop is constant and its movement is linearly correlated with the passed charge. If the direction of the current is changed, the drop moves in the opposite direction. The sensitivity of this type of coulometer depends on the diameter of the capillary.
See also
Notes
- ↑ Samuel Glasstone (16 April 2013). An Introduction to Electrochemistry. Read Books Limited. pp. 30–. ISBN 978-1-4465-4546-1. https://books.google.com/books?id=uzB8CgAAQBAJ&pg=PT30.
- ↑ Patrick/Fardo (18 October 2000). Industrial Electronics: Devices and Systems, Second Edition. CRC Press. pp. 474–. ISBN 978-0-8247-0501-5. https://books.google.com/books?id=xEreEcs1-2UC&pg=PA474.
- ↑ Although the indication of the zero charge of the metal is not needed, in discussing situations with charged AND uncharged particles, it clearly indicates the charge is not "forgotten".[citation needed]
- ↑ Curtis Instruments, Inc.. "Electro-Chemical Elapsed Time Indicators". https://www.surplussales.com/Meters/pdf/mtr-620pc_PDF.pdf.
- ↑ Stabler, H.P. (1962-10-01). "Electrochemical Elapsed Time Meter". American Journal of Physics 30 (10): xv–xv. doi:10.1119/1.1941803. ISSN 0002-9505.
Original source: https://en.wikipedia.org/wiki/Mercury coulometer.
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