Weston cell

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Drawing from Edward Weston's US Patent 494827 depicting the standard cell. Westoncell Volt.png
Drawing from Edward Weston's US Patent 494827 depicting the standard cell.
Weston cell Weston cell - Hanford B Reactor - Benton County, Washington.jpg
Weston cell
Standard cell, extracted from case. Made in USSR Standart cell.jpg
Standard cell, extracted from case. Made in USSR

The Weston cell or Weston standard cell is a wet-chemical cell that produces a highly stable voltage suitable as a laboratory standard for calibration of voltmeters. Invented by Edward Weston in 1893, it was adopted as the International Standard for EMF from 1911 until superseded by the Josephson voltage standard in 1990.

Contents

Chemistry

The anode is an amalgam of cadmium with mercury with a cathode of pure mercury over which a paste of mercurous sulfate and mercury is placed. The electrolyte is a saturated solution of cadmium sulfate, and the depolarizer is a paste of mercurous sulfate.

As shown in the illustration, the cell is set up in an H-shaped glass vessel with the cadmium amalgam in one leg and the pure mercury in the other. Electrical connections to the cadmium amalgam and the mercury are made by platinum wires fused through the lower ends of the legs.

Anode reaction
Cd(s) → Cd2+(aq) + 2e
Cathode reaction
(Hg+)2SO2−
4(s) + 2e → 2Hg(l) + SO2−
4(aq)

Reference cells must be applied in such a way that no current is drawn from them.

Characteristics

The original design was a saturated cadmium cell producing a 1.018638  V reference and had the advantage of having a lower temperature coefficient than the previously used Clark cell. [1]

One of the great advantages of the Weston normal cell is its small change of electromotive force with change of temperature. At any temperature t between 0 °C and 40 °C,

Et/V = E20/V − 0.0000406 (t/°C − 20) − 0.00000095 (t/°C − 20)2 + 0.00000001 (t/°C − 20)3.

This temperature formula was adopted by the London conference of 1908 [2]

The temperature coefficient can be reduced by shifting to an unsaturated design, the predominant type today. However, an unsaturated cell's output decreases by some 80 microvolts per year, which is compensated by periodic calibration against a saturated cell.

See also

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Transport Number is the ratio of the current carried by a given ionic species through a cross section of an electrolytic solution to the total current passing through the cross section. Differences in transport number arise from differences in electrical mobility. For example, in an aqueous solution of sodium chloride, less than half of the current is carried by the positively charged sodium ions (cations) and more than half is carried by the negatively charged chloride ions (anions) because the chloride ions are able to move faster, i.e., chloride ions have higher mobility than sodium ions. The sum of the transport numbers for all of the ions in solution always equals unity:

References

  1. Northrop, Robert (2005). introduction to instrumentation and measurements (2 ed.). p. 14. ISBN   978-1-4200-5785-0.
  2. "Electric units and standards". Circular of the National Bureau of Standards. 1916 (58). Washington, D.C.: USA Government Printing Office: 39. 25 September 1916. Retrieved 12 July 2016.

Literature

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