Editing Electrometer (section)

== Historical electrometers ==
=== Gold-leaf electroscope ===
[[Image:Electroscope.png|thumb|200px|upright|Gold-leaf electroscope]]
{{main|electroscope}}
The gold-leaf electroscope was one of the instruments used to indicate electric charge.<ref name=EB1911/> It is still used for science demonstrations but has been superseded in most applications by electronic measuring instruments. The instrument consists of two thin leaves of gold foil suspended from an [[electrode]]. When the electrode is charged by [[electrostatic induction|induction]] or by contact, the leaves acquire similar electric charges and repel each other due to the [[Coulomb force]]. Their separation is a direct indication of the net charge stored on them. On the glass opposite the leaves, pieces of tin foil may be pasted, so that when the leaves diverge fully they may discharge into the ground. The leaves may be enclosed in a glass envelope to protect them from drafts, and the envelope may be [[vacuum|evacuated]] to minimize charge leakage. This principle has been used to detect ionizing radiation, as seen in the [[Quartz fiber dosimeter|quartz fibre electrometer]] and [[Kearny fallout meter]].

This type of electroscope usually acts as an indicator and not a measuring device, although it can be calibrated. A calibrated electrometer with a more robust aluminium indicator was invented by [[Ferdinand Braun]] and first described in 1887.  According to Braun, the standard gold-leaf electrometer is good up to about {{nowrap|800 V}} with a resolution of {{nowrap|0.1 V}} using an [[ocular micrometer]].  For larger voltages up to {{nowrap|4–6 kV}} Braun's instrument can achieve a resolution of {{nowrap|10 V}}.<ref>Ferdinand Braun, [https://zenodo.org/record/1757498#.YUicgH3TWUk "Ueber das electrische Verhalten des Steinsalzes"], ''Annalen der Physik'', vol. 31, pp. 855–872, 1887.</ref><ref>[https://www.orau.org/health-physics-museum/collection/electroscopes/electrostatic/braun.html "Braun Electroscope (early 1900s)"], ORAU Museum of Radiation and Radiology, retrieved 20 September 2021.</ref>

The instrument was developed in the 18th century by several researchers, among them [[Abraham Bennet]] (1787)<ref name=Baigrie/> and [[Alessandro Volta]].

=== Early quadrant electrometer ===
[[File:Early Quadrant Electrometer.png|thumb|upright=0.5|Early quadrant electrometer.]]

While the term "quadrant electrometer" eventually referred to Kelvin's version, this term was first used to describe a simpler device. Its body consists of an upright stem of wood affixed to a semicircle of ivory with angle markings. A light cork ball hangs by a string from a pivot at the center of the semicircle and makes contact with the stem. When the instrument is placed upon a charged body, the stem and ball become charged and repel each other. The amount of repulsion is quantified by reading the angle between the string and the stem off the semicircle, though the measured angle is not in direct proportion to the charge.<ref>{{cite book|last=Draper|first=John William|title=A textbook on chemistry|year=1861|publisher=Harper and sons|location=New York|page=[https://archive.org/details/bub_gb_HKwS7QDh5eMC/page/n133 119]|url=https://archive.org/details/bub_gb_HKwS7QDh5eMC}}</ref> Early inventors included William Henley (1770) and [[Horace-Bénédict de Saussure]].<ref name=Baigrie>{{cite book|last=Baigrie|first=Brian |title=Electricity and magnetism: A historical perspective|year=2007|publisher=Greenwood Press|location=Westport, CT|page=33}}</ref>

=== Coulomb's electrometer ===
[[File:Coulomb electrometer.png|thumb|upright=0.4|Coulomb electrometer]]

Torsion is used to give a measurement more sensitive than repulsion of gold leaves or cork-balls. It consists of a glass cylinder with a glass tube on top. In the axes of the tube is a glass thread, the lower end of this holds a bar of gum lac, with a gilt pith ball at each extremity. Through another aperture on the cylinder, another gum lac rod with gilt balls may be introduced. This is called the carrier rod.

If the lower ball of the carrier rod is charged when it is entered into the aperture, this will repel one of the movable balls inside. An index and scale (not pictured) is attached to the top of the twistable glass rod. The number of degrees twisted to bring the balls back together is in exact proportion of the amount of charge of the ball of the carrier rod.

[[Francis Ronalds]], the inaugural Director of the [[Kew Observatory]], made important improvements to the Coulomb torsion balance around 1844 and the modified instrument was sold by London instrument-makers.<ref name="Ronalds 2016">{{Cite book|title=Sir Francis Ronalds: Father of the Electric Telegraph|last=Ronalds|first=B.F.|publisher=Imperial College Press|year=2016|isbn=978-1-78326-917-4|location=London}}</ref> Ronalds used a thin suspended needle rather than the gum lac bar and replaced the carrier rod with a fixed piece in the plane of the needle. Both were metal, as was the suspending line and its surrounding tube, so that the needle and the fixed piece could be charged directly through wire connections. Ronalds also employed a [[Faraday cage]] and trialled photography to record the readings continuously. It was the forerunner of Kelvin's quadrant electrometer (described below).

=== Peltier electrometer ===
Developed by [[Jean Charles Athanase Peltier|Peltier]], this uses a form of magnetic compass to measure deflection by balancing the electrostatic force with a magnetic needle.

=== Bohnenberger electrometer ===
The Bohnenberger electrometer, developed by [[Johann Gottlieb Friedrich von Bohnenberger|J. G. F. von Bohnenberger]] from an invention by T. G. B. Behrens,<ref name=EB1911/> consists of a single gold leaf suspended vertically between the anode and cathode of a [[Zamboni pile|dry pile]]. Any charge imparted to the gold leaf causes it to move toward one or the other pole; thus, the sign of the charge as well as its approximate magnitude may be gauged.<ref name="Angell1877">{{cite book|author=John Angell|title=Elements of magnetism and electricity: with practical instructions for the performance of experiments, and the construction of cheap apparatus|url=https://books.google.com/books?id=y45PAAAAYAAJ&pg=PA169|access-date=26 May 2013|year=1877|publisher=W. Collins, Sons, & Co.|pages=169–}}</ref>

=== Attraction electrometer ===
Also known as "attracted disk electrometers",<ref name=EB1911/> attraction electrometers are sensitive balances measuring the attraction between charged disks. [[William Snow Harris]] is credited with the invention of this instrument, which was further improved by [[Lord Kelvin]].

=== Kelvin's quadrant electrometer ===
[[Image:Lord Kelvin quadrant electrometer engraving.jpg|thumb|200px|Lord Kelvin's Quadrant Electrometer]]

Developed by [[Lord Kelvin]], this is the most sensitive and accurate of all the mechanical electrometers. The original design uses a light aluminum sector suspended inside a drum cut into four segments. The segments are insulated and connected diagonally in pairs. The charged aluminum sector is attracted to one pair of segments and repelled from the other. The deflection is observed by a beam of light reflected from a small mirror attached to the sector, just as in a [[galvanometer]]. The engraving on the right shows a slightly different form of this electrometer, using four flat plates rather than closed segments. The plates can be connected externally in the conventional diagonal way (as shown), or in a different order for specific applications.

A more sensitive form of quadrant electrometer was developed by [[Frederick Lindemann]]. It employs a metal-coated quartz fiber instead of an aluminum sector. The deflection is measured by observing the movement of the fiber under a microscope. Initially used for measuring star light,{{citation needed|date=May 2013}} it was employed for the infrared detection{{citation needed|date=May 2013}} of airplanes in the early stages of [[World War II]].

Some mechanical electrometers were housed inside a cage often referred to as a “bird cage”. This is a form of [[Faraday Cage]] that protected the instrument from external electrostatic charges.

=== Electrograph ===
Electricity readings may be recorded continuously with a device known as an electrograph. [[Francis Ronalds]] created an early electrograph around 1814 in which the changing electricity made a pattern in a rotating [[resin]]-coated plate. It was employed at [[King's Observatory|Kew Observatory]] and the [[Royal Observatory, Greenwich]] in the 1840s to create records of variations in [[atmospheric electricity]].<ref name="Ronalds 2016"/> In 1845, Ronalds invented photographic means of registering the atmospheric electricity. The [[Photography#Science and forensics|photosensitive surface]] was pulled slowly past of the aperture diaphragm of the camera box, which also housed an electrometer, and captured ongoing movements of the electrometer indices as a trace.<ref>{{Cite journal|last=Ronalds|first=B.F.|date=2016|title=The Beginnings of Continuous Scientific Recording using Photography: Sir Francis Ronalds' Contribution|url=http://www.eshph.org/blog/2016/04/19/1642/|journal=European Society for the History of Photography|access-date=2 June 2016}}</ref> Kelvin used similar photographic means for his quadrant electrometer (see above) in the 1860s.