Substantia. An International Journal of the History of Chemistry 5(2): 97-120, 2021

Firenze University Press 
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ISSN 2532-3997 (online) | DOI: 10.36253/Substantia-1312

Citation: Kenndler E. (2021) Tit Capillary 
Electrophoresis and its Basic Principles 
in Historical Retrospect. Part 2. Elec-
trophoresis of Ions: the Period from its 
Discovery in 1800 till Faraday’s Lines 
of Electric Force in the 1840s. Sub-
stantia 5(2): 97-120. doi: 10.36253/Sub-
stantia-1312

Received: May 10, 2021

Revised: Jun 15, 2021

Just Accepted Online: Jun 16, 2021

Published: Sep 10, 2021

Copyright: © 2021 Kenndler E. This is 
an open access, peer-reviewed article 
published by Firenze University Press 
(http://www.fupress.com/substantia) 
and distributed under the terms of the 
Creative Commons Attribution License, 
which permits unrestricted use, distri-
bution, and reproduction in any medi-
um, provided the original author and 
source are credited.

Data Availability Statement: All rel-
evant data are within the paper and its 
Supporting Information files.

Competing Interests: The Author(s) 
declare(s) no conflict of interest.

Historical Articles

Capillary Electrophoresis and its Basic 
Principles in Historical Retrospect. 
Part 2. Electrophoresis of Ions: the Period from 
its Discovery in 1800 till Faraday’s Lines of 
Electric Force in the 1840s.

Ernst Kenndler

Institute for Analytical Chemistry, Faculty of Chemistry, University of Vienna, Vienna, 
Austria
E-mail: ernst.kenndler@univie.ac.at

Abstract. This review is the first in a series that deals exclusively with electropho-
resis of ions. Since in modern terminology “electrophoresis is the movement of dis-
persed particles relative to a fluid under the influence of a spatially uniform electric 
field”, electrophoresis is not limited to colloidal particles, it includes ions as well. The 
history of electrophoresis of ions therefore begins in 1800 at the same time as that 
of electrolysis, because the two phenomena are so inextricably linked “that one can-
not happen without the other” (Faraday, 1834). Between 1800 and 1805 about half 
a dozen different theories of electrolytic decomposition and the movement of the 
particles – for which we coin the term electrophoretic current – were formulated, 
all contributing to the discourse, but lacking consistency and none fully convincing. 
They are discussed nonetheless because most of them fell into oblivion, even though 
they are interesting for historical reasons. However, from 1805/1806 the predominant 
theory, formulated by Theodor von Grotthuß and independently by Humphry Davy 
assumed that polarized molecules of water or dissolved ions form chains between the 
two electrodes. Only the terminal atoms of these chains were in direct contact with 
the electrodes and were liberated by galvanic action, but are immediately replaced 
by neighboring atoms of the same type. This decomposition and recombination of 
the molecules driven by electric forces which follow the “action at a distance” princi-
ple like in Coulomb´s law takes place over the entire chains; they represent the elec-
trophoretic current. However, in 1833 Michael Faraday refuted all previous theories. 
Two of his groundbreaking findings were of particular importance for the electro-
phoresis of ions: one was that electricity consists of elementary units of charge. The 
ions thus carry one or integer multiples of these units. The other was the revolution-
ary theory of the electric lines of force in early 1840s, and of what was later called 
the electric field. With these findings Faraday fundamentally changed the previously 
prevailing view of the electrophoresis of ions.

Keywords: Ion electrophoresis, history, action at a distance, lines of electric force.

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98 Ernst Kenndler

1. INTRODUCTION

While the discovery of three phenomena - electroly-
sis, electrophoresis of colloids and electroosmosis - was 
discussed in Part 1 of our historical review about capil-
lary electrophoresis[1] the present Part 2 will focus on the 
ensuing studies of the electrophoresis of ions, along with 
the inextricably linked electrolysis.

Historic sources reveal that electrophoresis was 
discovered by Nicolas Gautherot in 1801[2] and inde-
pendently by Ferdinand Friedrich von Reuß in 1807.
[3, 4] However, both discoveries have in common that 
the experimenters observed the motion of colloids and 
coarse granular particles, dispersed in water, when the 
electrodes of a voltaic pile were dipped into the disper-
sion and the electric circuit was closed. The large size 
of the particles enabled the observation of the particle ś 
movement by naked eye. Yet, this was one of the rea-
sons why electrophoresis has been attributed to parti-
cles of this relatively large size over more than a century 
after its discovery. It is to note that IUPAC also shares 
this view and recommends that electrophoresis is “the 
motion of colloidal particles in an electric field”.[5] But 
this view fell short and was for good reasons expanded 
since nearly one century to ions, small charged particles 
of atomic or molecular size. At this point it is empha-
sized that colloids do not differ from ions only by their 
size, but also by their structure.1

Notwithstanding this difference, the updated and 
more generalized definition of electrophoresis current-
ly agreed by the majority of the scientific community 
reads that “electrophoresis is the movement of dispersed 
particles relative to a fluid under the influence of a spa-
tially uniform electric field”.2 According to this defini-
tion, electrophoresis encompasses a general principle.3 

1 Electrophoresis of colloids, as well as electroosmosis, belong to the 
class of electrokinetic phenomena. Colloids, to be precise, colloidal par-
ticles, are an own phase in a second phase, they form heterogeneous 
dispersions, in which the two phases form an electric double layer at 
their interphase. Ions, in contrast, form homogeneous solution with the 
continuous medium in which they are dissolved.
2 In our text, we usually added the adjective “charged” to the term “par-
ticle” as it facilitates its reading. However, this is not required and the 
adjective “charged” can be omitted. The reason is that an uncharged 
particle can move under the influence of a field by electroosmosis, but 
in this case it does not move relative to the fluid but just like the flu-
id. When the motion of an uncharged particle is caused by diffusion 
or convection, it does move relative to the fluid, but not caused by the 
electric field. Only a charged particle will definitely move in the field 
relative to the fluid due to the electrical force acting on it; therefore, the 
addition of the adjective is needless.
3 We think that it is necessary to account for this wider view of elec-
trophoresis, since it is at present mainly considered as a separation 
method only. In contrast, we endorse the above cited general defini-
tion (see. e.g. refs. [6] and [7.). It should be noted that this definition 

With regard to this broader view at electrophoresis, ref-
erence is made to the more detailed discussion in Part 
1 of this series.

Does this generalizing definition of electrophoresis 
lead to a dilemma concerning the date of its discovery? 
It was already inferred on the occasion of electrolysis 
in 1800 that dissolved ions migrate in their solutions 
under the influence of an electric field. This finding 
clearly corresponds to the criterion of electrophore-
sis. In contrast to colloids or coarse granular particles 
the motion of ions could not be directly followed visu-
ally due to their small size, but their migration and the 
direction in which they move had been proven indi-
rectly from their concentrations close to the electrodes 
and their decomposition products which were formed 
by the simultaneous electrolysis process. Contemporary 
researchers therefore concluded that ions undoubtedly 
also move by what we call electrophoresis, at the same 
time when electrolysis occurs.

We therefore consider the commencement of elec-
trophoresis, strictly speaking the electrophoresis of ions, 
to be the day when William Nicholson and Sir Antony 
Carlisle split water into gaseous hydrogen and oxygen by 
electrolysis[8, 9] with the newly discovered galvanic elec-
tricity.4 For William Cruickshank the migration of the 
parts of the decomposable “body” and their perplexing 
occurrence at the separate poles was a “mysterious” phe-
nomenon, for Humphry Davy ”the agency of galvanism is 
at present involved in obscurity”, and this unintelligible 
effect provoked an intense research of its causes.

The entire first series of our historical retrospect 
focuses exclusively on ions in solutions. This series about 
ions consists of this and of following articles and covers 
the period between 1800 and the end of the Long 19th 
Century in 1914,5 or what we termed in Part 1 the 1st 

applies to all dispersed particles, from the smallest inorganic ions up 
to viruses, bacteria and cells. Moreover, in none of the definitions or 
recommendations electrophoresis is limited to separation methods. 
Note that neither Gautherot nor von Reuß, the classical discoverers of 
electrophoresis, carried out separations. So we find no sound reason 
not to base the view on electrophoresis on the general principle out-
lined above. In this sense electrophoresis is not a separation method, 
but can be utilized as such.
4 We briefly mention that a different terminology was used in the origi-
nal documents compared to the current ones. Even the term electropho-
resis was unknown until the Short 20th Century. In the present article 
we use – ahistorically – the modern terminology, but occasionally also 
the contemporary one of the original works, for instance when we quote 
verbatim. “Pole”, i.e., was substituted by “electrode” not until 1833.
5 We borrowed the term Long 19th Century from Eric Hobsbawm’s trilo-
gy on European history between the French Revolution in 1879 and the 
begin of World War I in 1914. It is the same period of time, in which all 
the main principles and theories of electrophoresis were already known, 
but – surprisingly – no attempts were made in this “1st epoch” to use 
them for a separation method; see Part 1.[1]



99Capillary Electrophoresis and its Basic Principles in Historical Retrospect.

epoch of electrophoresis. We repeat that the electrophore-
sis of colloidal particles is not included, since its history 
cannot be told without that of the ions. A historical ret-
rospect of electrophoresis of colloids, together with that 
of electroosmosis, will be the topic of a future separate 
series of articles.

The narrative in the present Part 2 of this series 
about ions spans the period from the discovery of elec-
trolysis in year 1800 to the 1840s. In those 1840s, 
Michael Faraday overthrew the hitherto established con-
cept of the action at a distance by the introduction of 
the groundbreaking theory of the lines of electric force or 
lines of action (later called field lines of the electric field).

One would expect this Part 2 to continue with elec-
trophoresis only. However, it is inevitable to consider 
that the theories of electrophoresis would have remained 
in the dark without the results obtained by electrolysis. 
Indeed, one can argue that the theories about electro-
phoresis had their roots in the conclusions drawn from 
the experimental results of electrolysis.

Before we begin the historical review of the devel-
opment of electrophoresis, we would like to mention 
briefly that almost all technical terms, with the excep-
tion of galvanic electricity, which have been used so far 
in this text, were unknown at this point in time. More-
over, the term electrophoresis remained unknown even 
during the Long 19th Century. Still, we find it useful to 
coin a new term in the present part. Our motivation is 
that in the early literature the complete electrical cur-
rent flowing during electrolysis was expressed by many 
different and ambiguous phrases such as “the flow …, 
the transmittance …, the transfer …, the transmission 
of electricity, ... the transport of galvanic electricity” and 
several others. However, this complete current consists 
in two different forms. The galvanic current is the cur-
rent of electrons in the metallic conductors of the cir-
cuit, and differs principally from the flow of charges 
which are carried by the dissolved ions. Hence, we 
think we have every reason to merge the various his-
torical and confusing expressions for the flow of the 
charges by ions in solutions into the single and unam-
biguous term electrophoretic current .6 This term is not 
usual, but it is to the point, and is full in line with the 
definition of electrophoresis.

6 We coin the term electrophoretic current analogue to the term galvanic 
current. We mention, however, that we are not consistently replacing the 
various terms used at that time by electrophoretic current. We replace 
them when it is appropriate in the context.

2. HOW DOES ELECTRICITY FLOW THROUGH 
WATER OR THROUGH SOLUTIONS OF 

COMPOUNDS DISSOLVED THEREIN DURING THEIR 
DECOMPOSITION?

In the beginning of research in the effect of gal-
vanic electricity on water7 and its electrolyte solutions, 
researchers in Britain dominated this area for the first 
two years after its discovery. Admittedly, their investiga-
tions were rather directed on the chemical transforma-
tion of the constituents of the liquid at the electrodes 
by electrolysis than on the f low of the electric cur-
rent through the liquid. Their findings were published 
mainly in Nicholsoń s Journal,8 which served them as a 
kind of “Central Organ”. This can be said considering 
the remarkable large number of the appropriate papers 
in Volume IV from 1801, which was the first to publish 
articles on this subject. The title page of this volume of 
historic merit is shown in Figure 1.

It was the volume where William Nicholson reported 
the discovery of the decomposition of water by galvanic 
electricity.[9] In addition, in the same volume William 
Cruickshank proposed a first theory of electrolysis and – 
please note – the inextricable linked transport of electrified 
particles of atomic size in solution between the poles.[11]

2.1 September 1800: The first theories by William Cruick-
shank and by Johann Wilhelm Ritter

2.1.1 W. Cruickshank´s theory of the oxygenated and the 
deoxygenated electric fluid

William Cruickshank, a friend of Nicholson,9 was 
the first who reported his investigations on the present 

7 It is important to realize that through the period under consideration 
water that was used for the experiments was never pure, but was always 
contaminated with impurities. Even when it was distilled, it certainly con-
tained electrolytes. Water with highest purity was first obtained around 
1890 by Adolf Heydweiller, a coworker of Friedrich Kohlrausch, after 
fiftyfold distillation under vacuum in a quartz apparatus. We mention 
this fact because the detailed process of the electrolytic decomposition of 
water depends on its purity, and on the kind of the contaminants or on 
the intentionally added compounds such as acids, bases or salts. Acidu-
lation, for instance, increases the speed of the generation of the gases. In 
this context, Faraday stated in 1834 that “even water itself, which so eas-
ily yields up its elements when the current passes, if rendered quite pure, 
scarcely suffers change, because it then becomes a very bad conductor”.[10]
8 This periodical journal was founded in 1797 and published by William 
Nicholson entitled Journal of Natural Philosophy, Chemistry & the Arts. 
It was commonly called Nicholson´s Journal, and merged in 1814 with 
the Philosophical Magazine to The Philosophical Magazine and Journal, 
later named The Philosophical Magazine. Please note the combination of 
natural philosophy, chemistry and arts at the time.
9 There is not a very detailed record of William Cruickshank`s life. He 
was born in north-east Scotland in the 1740s or 1750s. Known is that in 



100 Ernst Kenndler

topic, remarkably as early as July 1800 in Nicholson ś 
Journal.[11] Cruickshank began his experiments by 
repeating those of Nicholson and Carlisle, albeit with 
another device. Briefly, he used a horizontally placed 
glass tube, completely filled with water, with both open-
ings closed with cork stoppers.10 Then he inserted wires 
made from silver through the corks at each end into the 
water and connected them with a voltaic pile composed 
from plates of silver and zinc. After completing the cir-

1765 he received his master from King’s College in Aberdeen and later a 
diploma from the Royal College of Surgeons of England. In 1788 he got 
a position as assistant at the Royal Military Academy, and as lecturer in 
1796 until 1804. He died in 1810 or in 1811 in Scotland. In addition to 
his first theory of the decomposition of water, he invented the trough 
battery.[12]
10 Unfortunately, in the original paper in Nicholson´s Journal the draw-
ings of the devices were not printed, because Cruickshank missed the 
deadline to submit them. Their schematic reproductions are found in 
the comprehensive and detailed study about electricity from 1751 till 
1807 by Amy Alice Fisher.[13]

cuit, he observed that gases were evolved at the two 
poles, with hydrogen at the silver wire and oxygen at the 
zinc wire.11 In addition, he observed corrosion of the zinc 
wire. Upon adding a tincture of litmus or Brazil wood, 
and carrying out the experiment again, he observed that 
at the zinc wire the water became acidic, at the silver 
wire alkaline, effects that were noted also by others. He 
decomposed also “metallic” solutions, that are solutions 
of salts of metals. With silver dissolved in nitrous acid 
he got a precipitate of needle-like crystals in the form of 
arbor Dianae.12

In the same paper he tried to find out how far the 
influence of galvanic electricity is reaching. To this end, 
he connected two tubes described above for their com-
munication by a silver wire, a 1st class conductor, that 
was passed through a cork of each tube. After closing 
the circuit, he observed the usual corrosion or disen-
gagement of gases at the poles, what convinced him that 
an even greater number of tubes connected in series 
would give a similar result.

In the subsequent article in the issue of September 
1800,[14] Cruickshank addressed that significant prob-
lem which was incomprehensible since its discovery: the 
occurrence of the individual gases in the water at the 
two different poles when galvanic current is applied. To 
attempt to solve this, Cruickshank used single tubes as 
described above, and carried out a series of quantitative 
measurements of the gases which evolved under vari-
ous conditions. Based on his findings he formulated the 
first theory of the transport of the particles which were 
decomposed during electrolysis (ref. [14], pp. 257, 258). 
For water as liquid, Cruickshank hypothesized that the 
“galvanic influence (whatever it may be) is capable of 
existing in two states, that is, in an oxygenated and deox-
ygenated state”. Since its affinity for oxygen is weaker 
than for solid metals, Cruickshank assumed that upon 

11 One has to differentiate Cruickshank´s designation of the metals of 
the wires inserted into the liquid in which decomposition occurs, on 
the one hand, and of the plates of the voltaic pile, on the other hand. 
This terminology was later used by others, but not by everyone. Cruick-
shank, who applied the common configuration of the pile, which was 
made from plates of silver and of zinc, did not define the poles as posi-
tive or negative. He stated instead; “In future, to avoid circumlocution, 
I shall call the wire attached to the silver plate, the silver wire, and the 
other the zinc wire.” This terminology did not define the metal of the 
wire (e.g. gold, silver, platinum, iron, etc.), which was occasionally used 
as pole immersed into the liquid under study, it refers to the metals of 
the pile`s plates onto which the wires were attached. We will italicize 
these wires regardless of their metal. In the present example, it could be 
confusing because both wires consist of silver.
12 arbor Dianae, Lat. tree of Diana, also philosopher’s tree, Lat. arbor 
philosophica, the silver tree, is formed when silver is precipitated from 
a silver salt solution by reduction. It has a shape like a tree, and consists 
of crystals of silver or silver amalgam. These trees were named by alche-
mists relating to the name for silver, Diana.

Figure 1. Title page of the remarkable Volume IV of Journal of Nat-
ural Philosophy, Chemistry and the Arts, called Nicholson’s Journal. 
In this Volume from 1801, in the six issues from July to December 
1800 the notable number of 13 papers (out of a total of 58) were 
published which exclusively dealt with galvanic action.



101Capillary Electrophoresis and its Basic Principles in Historical Retrospect.

the deoxygenated “galvanic influence” (probably some-
what like a galvanic electric fluid) from the silver wire 
enters the water, disrupts it into its components and 
seizes the free oxygen, whereby hydrogen gas is segre-
gated. Then, the electric fluid, together with the oxygen, 
passes the water to the opposite pole, where the oxygen 
is transferred to the zinc wire, and is released as a gas. 
Eventually, after transmission of the oxygen, the deoxy-
genated electric fluid flows back to the pile. Note that 
Cruickshank believed that the two evolving elements 
came from the same water molecule.

In case that the interposed liquid is a solution of a salt 
from a metal, the deoxygenated electric fluid passes from 
the silver wire, seizes the oxygen of the metal calx, trans-
ports it to the zinc wire, where oxygen is released and the 
deoxygenated electric fluid enters the metallic pole.

Yet, Cruickshank recognized the somewhat incon-
sistent suppositions of his theory, and finally conceded:

“In ref lecting on these experiments it would appear, 
that (….) the water must be decomposed; but how this 
can be effected, is by no means so easily explained. For 
example, it seems extremely mysterious how the oxygen 
should pass silently from the extremity of the silver wire 
to that of the zinc wire, and there make its appearance 
in the form of a gas.” (ref. [14], p. 257; note the attribution 
“extremely mysterious.”)

In the aforementioned Vol. IV of Nicholsoń s Jour-
nal also other researchers, e.g. William Henry, Col. Hen-
ry Haldane and Humphry Davy reported the electroly-
sis of water, and all agreed that water is a compounded 
body, composed from about two parts of hydrogen and 
one part of oxygen. However, one researcher, Johann 
Wilhelm Ritter from Jena in Germany, one of the most 
passionate followers of the Romantische Naturphiloso-
phie (Romantic Nature Philosophy),13 was strictly con-
vinced that water was an undecompounded body, a 
chemical element.

2.1.2 September 1800: J. W. Ritter’s theory of the meta-
morphosis of water by galvanic action

Johann Wilhelm Ritter was the opponent of the 
current hypothesis of the electrolysis of water (please 
pay heed to footnote 14) He believed that water does not 

13 Ritter was strongly influenced by Friedrich Wilhelm Joseph Schell-
ing, the main philosopher of the Romantischen Naturphilosophie “The 
Romantic Nature Philosophy considered the human being as a whole in 
the system of nature. Philosophy provided a system of thought from which 
the events of nature observation can be read.” Transl. from ref. [15], p. 23.
14 Johann Wilhelm Ritter (1776, (Samitz (Zamienice) near Haynau 
(Chojnów), Silesia - 1810, Munich) was a German physicist (initially 

decompose under galvanic action and therefore forma-
tion and migration of ions do not occur. That may sound 
like a paradox, taking into account that he was the first 
researcher in Germany who experimentally fractionated 
water into gaseous hydrogen and oxygen using galvanic 
electricity. We find him noteworthy in the present his-
torical retrospect not only because he pioneered the 
research in galvanism in Germany (together with Theo-
dor von Grotthuß, see below), but also, due to his out-
standing and unusual personality in the scientific com-
munity. He was a somewhat strange person of vivid 
imagination, unusual mental agility and seemingly bor-
derless inventive creativity.15 Humphry Davy, for exam-
ple, characterized Ritter ś person and activities in his 
Bakerian lecture in 1826 (ref. [21], p. 385) as follows:

“Ritter’s work contains some very ingenious and 
original experiments on the formation and powers of 
single galvanic circles; (….) : and in the obscurity of 
the language and metaphysics (…..) , it is difficult to say 
what may not be found. In the ingenious, though wild 
views, and often inexact experiments of Ritter, there are 
more hints which may be considered as applying to elec-
tro-magnetism than to electro-chemistry, … ”.

Without having a regular income, Ritter began his 
research, notwithstanding the problems of getting access 
to the current literature sources in Jena16 where he con-
ducted his scientific and philosophical studies.[24] He 
carried out his experiments knowing only how to put a 
voltaic pile together, but without having knowledge of 
comparable experiments that were already done. None-
theless, he was able to complete his investigations and 
to publish his results as early as in September 1800,[25] 
remarkably just two months after Nicholson and Carl-
isle, and at the same date when Davy had completed his 
first experiments on this subject - albeit under relevantly 
better conditions. In his first experiments he subjected 
water to galvanic action with a simple, self-made device, 
and measured quantitatively the volumes of the two gas-

he was an apothecary), philosopher and an extraordinarily multifaceted 
personality. He can be considered as an outstanding scientist, but till at 
present time he is quite underestimated. Without never getting a posi-
tion at a university (he only became member of the Bavarian Academy 
of Science in 1804, see his portrait in Figure 2) he contributed as auto-
didact to galvanism, e.g. by the independent discovery of the electroly-
sis of water in September 1800. In the course of these experiments, he 
invented electroplating. He discovered UV-radiation in 1801,[16]. and 
invented the dry cell battery in 1802. Ritter built the battery from 600 
zinc-copper plates. It reached a potential of more than 700 Volt. In the 
last years of his live his interest turned, influenced by the German the-
osophist Franz Xaver von Baader, to siderism and radiesthesia..[17],[18],[19]. 
He died in poverty at the age of 33 by tuberculosis.
15 The character of the protagonist is borrowed from the real person 
Johann Wilhelm Ritter in the novel “Die Unglückseligen” (The Unfortu-
nate Ones) by the German woman writer Thea Dorn.[20]
16 See e.g. his letter to Horkel.[23]



102 Ernst Kenndler

es which were separately generated at the electrodes by 
collecting them in two tubes after closing the circuit.17 
Although Ritter identified the two gases as oxygen and 
hydrogen in roughly the correct proportions of one to 
two and a half volumes, he asked himself the same ques-
tion that British researchers did, namely

“Kann sich aber das nemliche Atom Wasser in einem und 
dem nemlichen Augenblicke zugleich an diesem und wie-
der an jenem Drathe befinden ? – Und doch müßte das 
der Fall seyn , wenn beyde Gasarten , beyde Stoffe, das 
Oxygen und Hydrogen , von einer wirklichen Zersetzung 
des Wassers herrührten.” (But can the same atom of water 
be on this and on that wire at the same moment? – And 
yet this would have to be the case if both types of gas, 
both substances, oxygen and hydrogen, resulted from a 
real decomposition of water.)

Ritter could ignore this problem because he believed 
that water was an element and not a molecule. He was 

17 A drawing of this device is depicted on p. 372, (Fig.3, Tab.V) of Voi-
gt´s Magazin, ref. [25].. The complete name of this little-known journal 
was Magazin für den neuesten Zustand der Naturkunde mit Rücksicht 
auf diedazu gehörigen Hilfswissenschaften, herausgg. von Johann Heinrich 
Voigt.

convinced that the collected hydrogen and oxygen were 
not decomposition products of water, but they were 
still water which was transmuted into other forms. As a 
proof for his conviction he filled a V-shaped glass tube 
(depicted in Figure 3) halfway with concentrated sulphu-
ric acid, and covered the acid meticulously on both side 
pieces with distilled water, taking care to avoid any mix-
ing of the two liquids.[25] The acid was intended to act as 
a barrier to prevent the transfer of water or of its com-
ponents through the acid and thus to the opposite side 
piece. To this end he selected concentrated and rectified 
sulfuric acid after testing that it did conduct electricity,18 
but did not evolve even a trace of gas under the action of 
galvanic electricity.

Ritter dipped one pole through the one, the oth-
er pole through the other opening of the tube into the 
water, completed the electric circuit, and observed the 
immediate and separate formation of gaseous hydrogen 
and oxygen at the individual poles (a and b in the origi-
nal “Fig. 15”) without any gas showing anywhere else in 
the tube between a and b.

After he had executed several similar experiments 
and obtained the same results; he concluded (p. 390)

“So ist es also durch Versuche nun nicht bloß auf das 
Vollständigste erwiesen: daß die bey der Einwirkung des 

18 The conscientious experimenter Michael Faraday found the very 
reverse and explained “681. On experimenting with sulphuric acid, I 
found no reason to believe that it was by itself a conductor of, or decom-
posable by, electricity” and continued “When very strong it is a much 
worse conductor than if diluted”.[10]. This comment suggests that Ritter’s 
sulphuric acid still contained traces of water.

Figure 2. Portrait of Johann Wilhelm Ritter, wearing the uniform 
of the Bavarian Academy of Sciences. About 1804. Unknown artist. 
Taken from ref. [22].

Figure 3. The V-shaped glass tube with side pieces of 2 German 
inches (i.e. about 3 cm) in length was first filled halfway with pure 
concentrated sulphuric acid. The acid was then overlaid with dis-
tilled water, into which the two poles a and b were dipped. The 
poles, made from gold, were connected with the voltaic pile. Taken 
from ref. [26], after p. 326, Taf. 1, Fig. 15.



103Capillary Electrophoresis and its Basic Principles in Historical Retrospect.

verstärkten Galvanismus auf Wasser erzeugten beyden 
Gasarten, das Hydrogen wie das Oxygen, keinesweges 
von einer sogenannten Zersetzung des Wassers herrüh-
ren können, sondern überdies noch: daß auch die Erzeu-
gung jeder einen Gasart ein Proceß sey, der ganz und 
gar nicht mit dem der Erzeugung des anderen zusam-
menhänge, sondern daß, beyde durchaus unabhängig 
voneienader, und einzeln, Statt haben können.” (Thus, it 
is not only proved to the most complete extent by exper-
iments: that the two types of gas, hydrogen and oxygen, 
produced by the action of the amplified galvanism on 
water can´t at all result from a so-called decomposition 
of water, but, moreover, that the generation of each type 
of gas is also a process which is in no way connected 
with that of the generation of the other, but that both 
can take place entirely independently of one another and 
individually.)

These results convinced Ritter once and for all to 
have demonstrated that water on both sides was in fact 
independently transmuted by a kind of metamorphosis 
into another modification by electricity, but not decom-
posed.19 He took this result as evidence that oxygen is 
water minus electric fluid, and hydrogen is water plus 
the electric fluid, but they still remain elemental water.

A severe disadvantage to follow Ritter’s argumenta-
tion was his circuitous and protracted style of writing, 
which was very difficult to understand - even for native 
speakers. This peculiarity was communicated by the 
Anglo-Irish physician and mineralogist William Babing-
ton20 in a letter dated December 1800, entitled “On the 
State of Galvanism and other Scientific Pursuits in Ger-
many” and printed in Nicholsoń s journal.[27] Neverthe-
less, von Grotthuß acknowledged Ritter (ref. [28], p. 113) 
that he – although he never graduated from university 
– possessed the ability and acumen to refute all theories 
proposed prior to 1805 about the flow of electricity dur-
ing the electrolysis of water (see ref. [29]).

19 Ritter carried out all these experiments in Jena within days, namely 
from September 28 to 30, 1800.
20 William Babington (1756, Portglenone near Coleraine, Irland - 1833) 
reported, for instance, in his letter to the editor: “…The principal galvan-
ic discoverer here is a young man, called Ritter, at Jena, in Saxony: about 
two years since he published the result of his almost innumerable experi-
ments, in which he established all its laws, and anticipated almost all the 
newer experiments. Unfortunately the book was written very obscurely, 
and was still more obscured by the language of the newer philosophy. ….. 
this suggested to him to interpose some substance between the extremities 
of the wires, which was at the same time capable of conducing the gal-
vanic influence, and of remaining perfectly unaltered by it.  …. thus it is 
proved, that water under certain circumstances, may be wholly converted 
into oxygen gas, and under others, into hydrogen-gas; the rationale of this 
phaenomenon is as yet in obscurity”. The present author illustrates his 
intricate and circuitous style by one example taken from pages XXI and 
XXII of his book about Siderism: one single sentence, which is com-
posed of many subordinate clauses and nested sentences, consists of the 
remarkable number of 297 words.[17]

Ritter published his theory in September 1800, at 
exactly the same date as Cruickshank. So there are two 
philosophers who could have claimed priority, although 
their theories could not be more different, but the credit 
goes to only Cruickshank. Only his theory deals with 
the motion of particles, a criterion of electrophoresis. 
However, in the end, Cruickshank ’s theory as well as 
Ritteŕ s theory of the “Einfachheit des Wassers” (“elemen-
tariness of water”)[24, 30] soon failed due the investigations 
of Davy, von Grotthuß, and others.

2.2 Other theories from 1800 till 1805

In autumn 1800 Humphry Dav y, too, wondered 
whether the formation of oxygen or hydrogen gas took 
place when the water is filled into separate vessels (each 
connected to the pile with a wire). The water was not in 
direct contact in Davy ś experiments either, but in con-
trast to one of Cruickshank ś devices (in which the two 
tubes were connected by a silver wire), it communicated 
through 2nd class conductors.[31] First, Davy closed the 
electric circuit by dipping the fingers of his right and 
his left hand into the water in the separate vessels, and 
observed the disengagement of gases at the poles. The 
gases were also generated when communication was 
through three persons, or by connecting the two ves-
sels with muscular or living plant fibers, respectively, or 
with moistened thread, all acting as 2nd class conduc-
tors. This result led him to conclude that not only gal-
vanic current in the metallic wires, but also the flow of 
the current by electrified bodies in the connecting wet 
organic matter enabled the communication of the water 
in the separate vessels.

Davy investigated, in addition to that of water, the 
electrolysis of aqueous solutions of various acids and 
bases. He found, among other effects, that pure hydro-
gen was always generated at the one pole, but at the other 
pole oxygen was either released as gas or it oxidized the 
metal of the wire. He published his results between Sep-
tember and December 1800 in three papers in the notable 
Vol. IV of Nicholsoń s Journal mentioned above.[31-33]

Nevertheless, af ter having executed numerous 
experiments Davy restrainedly summarized in Decem-
ber 1800 his attempts to clarify these difficult to under-
stand invisible motion through water and other men-
strua. He stated (ref. [33], p.400)

“Many new observations must be collected, probably 
before we shall be able to ascertain whether water is 
decomposed in galvanic processes. Supposing its decom-
position, we must assume, that at least one of its elements 
is capable of rapidly passing in an invisible form through 



104 Ernst Kenndler

metallic substances, or through water and many connect-
ed organic bodies; and such an assumption is incommen-
surable with all known facts.”

It is worth noting that at the turn of 1800 to 1801 
in Germany four researchers independently realized that 
the order of the metal plates on the voltaic pole built by 
earlier philosophers was misleading. In the past, the pile 
was composed of plates of zinc (Z) and silver (A) with an 
interposed wetted layer (w) in the sequence [-SZwSZw…
SZwSZ+]. But K. W. Böckmann,[34] A. von Arnim, who 
entitled his paper “Über die Benennung der Endpole der 
Voltaische Säule“ (On the designation of the end poles of 
the Voltaic pile),[35] P. Erman[36] and W. Gruner[37] dis-
covered that the proper sequence of the pile should be 
[-ZwSZwS...ZwS+], which is obtained by omitting the 
zinc and the silver plate, respectively, at the two extremi-
ties of the earlier pile.21 We can especially recommend 
reading the expounded and informative comments of 
the highly competent editor of Ann. Phys., Ludwig Wil-
helm Gilbert, on Ermań s[38] and on von Arnim ś[39] con-
tributions.22

However, at the European Continent several other 
theories of electrolysis and the electrophoretic current 
were formulated in these years. This happened for the 
most part in Germany, France, Italy, and in Sweden. 
In Germany, among others, Paul Ludwig Simon (1771 
- 1815, Berlin), professor at the Building Academy in 
the faculty of architectural physics in Berlin,[40, 41] and 
Christian Heinrich Pfaff, professor of medicine, physics 
and chemistry in Kiel,[42] stepped forward with theories 
of the action of electricity on water which are not going 

21 Karl Wilhelm Böckmann (also Boeckmann) (1773 - 1821, Karlsru-
he), physicist and chemist, professor for physics. (Carl Joachim Fried-
rich Ludwig) “Achim” von Arnim (1781, Berlin – 1831, Wiepersdorf ), 
Göttingen. Paul Erman (1764 - 1851, Berlin), professor for physics in 
Berlin. Johann Ludwig) Wilhelm Gruner (1771, Halle on Saale – 1849), 
court apothecary in Celle.
22 In von Arnim´s paper Gilbert (1769, Berlin – 1824, Leipzig) wrote as 
a part of a comprehensive comment somewhat caustically: “… Wenn 
also Nicholson seine Voltaischen Säulen auf folgende Weise errichtet: S., 
Z., fL., S., Z., fL., S....Z., fL., S., Z., so sind die erste Silber- und die letzte 
Zinkplatte der Säule offenbar überflüssig und nicht als Glieder der galva-
nischen Ketten, sondern bloß als ein willkürlich hinzugefügter Metallleiter 
zu betrachten, der, ohne etwas zu ändern, so gut fehlen als da seyn kann. 
Nach ihnen den ersten Pol den Silberpol, und den letzten den Zinkpol zu 
nennen, wie man es bisher gethan hat, ist daher gewiß unschicklich und 
verwirrend, ... “ (So if Nicholson builds his voltaic pile in the following 
way: S., Z., fL., S., Z., fL., S....Z., fL., S., Z., the first silver- and the last 
zinc plate of the pile is evidently superfluous but to be considered merely 
as an arbitrarily added metal conductor, which can be lacking as well as 
be present, without changing anything. Terming the first pole the silver 
pole and the last the zinc pole, as has been done thus far, is therefore cer-
tainly improper and confusing. ... ). [fL. stands for the wetted layer; the 
author].

to be discussed further.23
In France A. F. Fourcroy, L.- N. Vauquelin and L. 

J. Thénard24 published a number of papers in Magasin 
Encyclopédique, ou Journal des Sciences, des Lettres et 
des Arts. In 1800 and 1801. In 1801 Citoyens Fourcroy 
and Vauquelin hypothesized the circulation of the elec-
tric fluid from the positive to the negative pole. They 
assumed that this fluid decomposes water at the positive 
wire, where oxygen is released as gaseous bubbles. There, 
the positive fluid combines with hydrogen, and the com-
bined hydrogen is transported unseen by an assumed 
fluidum deferens, the galvanique, to the negative wire. 
The galvanique enters this wire, whereupon the hydro-
gen is evolved as gas bubbles.25

An “electric acid ” (“l´ossielettrica”), an expansive 
liquid with fineness like heat and light, smelling simi-
lar to phosphorus, and tasting pungently was conjec-
tured in 1800 by Luigi Valentino Brugnatelli (1761 - 
1818, Pavia), professor of chemistry in Pavia, Italy, and 
friend of Volta.[44, 45] According to his theory, the electric 
acid easily enters the metals, and dissolves them – such 
as water dissolves a salt – as soon as it is set in motion 
(“quando l ósielletrico é in moto”). It is soluble in water, 
and in such a dissolution most metals are oxidized at 
the expense of water, whereupon hydrogen is formed 
through decomposition. The metal oxides formed by 
this reaction combine with the electric acid under for-
mation of metal électrates (“osielettrati”). For example, 
the électrate of copper is green, that of silver is white, 
both are transparent and insoluble in water. Their most 
pronounced capability is that they can be carried away 
through the water by the electric acid over comparably 
long distances. Finally, the électrates are precipitated at 
the metal of the pole as salt-like crusts.26

23 Paul Ludwig (also Paul Louis) Simon (1771, Berlin – 1815, Berlin); 
Christoph Heinrich Pfaff (1773, Stuttgart - 1852, Kiel).
24 Antoine François, comte de Fourcroy (1755 - 1809, Paris); Louis-Ni-
colas Vauquelin (1763 – 1829, Saint-André-d’Hébertot, Normandy); 
Louis Jacques de Thénard (1777, La Louptière, near Nogent-sur-Seine 
(Aube) - 1857, Paris).
25 Their hypothesis is published in Séance publique de l´Ecole de mêd-
icine de Paris, du 24 vendèmiaire an 10, [Sept. 24,1801; the author] 
in-4°., page 67. and reads: “Les CC. Fourcroy et Vauquelin, …, admettent 
l´existance d´un fluide particulier, qu´ils nomment galvanique, et qui cir-
cleroit du côté positif de la pile, vers le côté négatif. Selon eux, ce fluide 
décompose l´eau en sortant du côté positif: il laisse échaper l´oxygène en 
bulles; mais il se combine avec l´hydrogène pour former un liquid, lequel 
traverse l´eau, …. , pour aller gagner l´extrémité du fil négatif. Là le gal-
vanique abandonne son hydrogène, et le laisse échapper à son tour sous 
forme de gaz, tandis que lui-même pénètre dans le fil.” (ref. [43], p. 157.)
26 Alessandro Volta explicitly distanced himself from Brugnatelli´s theo-
ry and stated in ref. [46]., p. 264, “Ich habe keinen Antheil an seinen Mei-
nungen oder Ideen über die electrische Säure, die electrisch-sauren Metalle, 
u.d. m.“ [Ann. Phys. (Gilbert ed.) XIV (7), p. 264.] (“I have no share in 
his opinions or ideas about the electric acid, the electric-acidic metals, etc).”



105Capillary Electrophoresis and its Basic Principles in Historical Retrospect.

To his surprise, when he visited Paris with Volta, 
Brugnatelli found a paper in the issue of August, 1801 
(le 11 fructidor an 8) of Ann. Chim., authored by the 
Belgian Étienne-Gaspard Robert. Around 1800 Robert 
executed experiments with galvanism, and read one of 
his works before l’Institut National de France in August 
1801, which was published in the aforementioned Ann. 
Chim., entitled “Expériances nouvelles sur le fluide galva-
nique”.[47] He proposed a theory which was very similar 
to Brugnatelli ś,27 and in which he termed Brugnatelli ś 
electric acid “l ácide galvanique”.

Robert was well-known by his stage name Stephan 
Kaspar Robertson, also Robert-son,28 whereby it was 
peculiar back then as it is today, why ask a professor of 
physics would choose a stage name.29

Due to his interest in many various areas. it was 
not surprising that the German physician Johann Frie-
drich Erdmann was fascinated by the recently discov-
ered galvanic electricity, and in its applications to medi-
cal issues.30 He decomposed water by electrolysis and 
obtained hydrogen and oxygen in right proportions 
as usual. In 1802 Erdmann put forward the hypothesis 
that galvanic electricity flows into the water at the + 
pole, and leaves it at the - pole.[56] By entering water at 
the + pole, it binds hydrogen, since the latter has a larger 
affinity to electricity than to oxygen, and thus oxygen is 
liberated. Hydrogen unites to hydrogenated electricity, 

27 Chapitre X. Expériences et observations sur le galvanism, par MM. 
Nicholson, Carlisle, Robertson, Cruickshank, Henry and Davy; ref. [48]., p. 
282 ff., §. II. Expériences et observations de M. Robertson, see p. 294.
28 The hyphen in Robert-son is not a printing error.
29 Robert had a remarkably eventful biography (see his Mémoires).[49],50]. 
Born in 1763 as Étienne-Gaspard Robert in Liège, Belgium, he studied 
at Leuven, and became professor of physics, specialized in optics, at 
l’école centrale du département de l’Ourthe. In 1791 he moved to Par-
is to strive for a career in art as a painter. There, he attended in 1792 
and 1793 the scary ghost-raising show Phantasmagorie, and easily fig-
ured out that the ghosts were created by the use of a Laterna Magica. 
He premiered his own show (under the stage name Robertson) in Paris 
in 1798 which he later performed with great success around the world. 
During these trips he became fascinated by ballooning and flew balloon 
shows in Vienna, Dresden, Leipzig, Moscow and other cities. He con-
sidered some flights by himself as being scientific, because he connected 
them with meteorological investigations. He managed to publish three 
of his flights in Ann. Phys. in 1804 as communications to the editor 
Ludwig Wilhelm Gilbert.[51],[52],[53]. It is interesting to read Gilbert´s crit-
ical comments and references to errors in Robertson´s reports, which 
make up a large part of the papers. Robert died in 1837 in Paris.
30 Erdmann (1778, Wittenberg - 1846, Wiesbaden) published, for 
instance, in 1803, one year after his doctorate in medicine, a paper 
entitled “Beschreibung zweier von Dr. Brunner in Wien erfundenen vol-
taisch-elektrischen Apparate zur Entdeckung des Scheintodts und zur 
Wiederbelebung der Scheintodten” (Description of two by Dr. Brunner 
in Vienna invented voltaic-electrical apparatus to discover the apparent 
death and to revive the apparent dead),[54] and in 1804 one about “Gal-
vanische Versuche, angestellt im Wiener Irrenhaus“(Galvanic experiments, 
employed in the Vienna madhouse).[55]

which traverses the liquid towards the - pole, where the 
electric matter intrudes the metal of the pole and hydro-
gen is released as gas.31

Since in the first years after 1800 the subject of most 
of the works was the decomposition of solutions of arbi-
trarily chosen salts, acids and bases by galvanic electric-
ity, it was quite difficult to find a coherent structure in 
the results obtained under these widely varying condi-
tions. This gap motivated the Swedes Wilhelm Hisinger 
and Jöns Jacob Berzelius “to search for as many as pos-
sible general results from the experiments we and others 
have performed, so that the phenomena” of the electric 
decomposition and the motion of the ions could be bet-
ter understood and even foreseen (ref. [57], p. 115 - 116). 
They published a systematic study of nearly thirty select-
ed electrolytes in 1803 in German translation[57] from 
Swedish and in 1804 in a condensed version in French.
[58] It can be said that this work did not contain really 
new aspects, but the categorization of the experimental 
outcomes enabled them to formulate certain valuable 
rules, which they summarized in seven points. We cite 
those rules which have a direct context to the motion of 
decomposed particles. They read32

“Versuch, aus den obigen sowohl, als aus anderen bekann-
ten galvanischen Versuchen, einige allgemeine Folgerun-
gen herzuleiten. 1. Wenn sich die electrische Säule durch 
eine Flüssigkeit entladet, so sondern sich die Bestand-
theile dieser Flüssigkeit dergestalt von einander ab, daß 
sich einige von ihnen um den negative Pol, andere um 
den positiven ansammeln. 2. Diejenigen Stoffe, die sich 
zum Drahte eines und desselben Poles hin begeben, ste-
hen unter sich in einer gewissen Analogie. Zum negativen 
Pol gehen alle brennbaren Körper, Alkalien und Erdar-
ten; zum positiven hingegen Sauerstoff, Säuren und oxy-
dierte Körper. 7. Wasser wird in Wasserstoff und Sauer-
stoff zerlegt, die aber in unzerlegtem Wasser unauflöslich 
sind, daher ersteres vom negativen, letzteres vom positi-
ven Draht, gasförmig entwickelt wird.” (Attempt to draw 
some general conclusions from the above, as well as from 
other known galvanic experiments. 1. If the electric col-
umn is discharged through a liquid, the components of 
this liquid separate from one another that some of them 
collect around the negative pole, others around the posi-
tive. 2. Those substances which move to the wire of one 
and the same pole stand in a certain analogy among 
themselves. All combustible bodies, alkalis and earths go 
to the negative pole; to the positive, on the other hand, 
oxygen, acids and oxidized bodies 7. Water is fragmented 

31 This paper was an extract of his doctoral thesis entitled “Utrum aqua 
per electricitatem columnae a cel. Volta inventae in elementa sua dissolva-
tur?“, which he defended on May 2, 1802, at the Medical Faculty of the 
famous Alma mater Wittenbergensis.
32 Points 3, 4, 5 and 6 are not directly relevant for the topic at hand, 
therefore we leave them out.



106 Ernst Kenndler

into hydrogen and oxygen, which, however, are insoluble 
in undecomposed water, so the former is developed in 
gaseous form from the negative, the latter from the posi-
tive wire.).

Hisinger and Berzelius interpreted their findings as 
the result of the electrostatic attraction and repulsion 
of the ions to and from the respective charged poles.[57] 
They assumed these electric forces to follow the principle 
of the action at a distance. In the concept of the action 
at a distance33 the forces are strongest at their poles and 
diverge then in the inverse ratio of the square of their 
distance. The two forces cross in the middle between the 
poles and compensate each other at the point of neutral-
ity or indifference point. Decomposition happens not 
at the poles, but near or at this point. This concept was 
later a key part of Humphry Davy ś theory of the elec-
trolysis and the motion of the decomposed particles.[62]

Hisinger and Berzelius were not really convinced of 
this hypothesis. They doubted the assumption of decom-
position at the point of indifference, as this contradicted 
what was observed in practice (ref. [57], p.148) Therefore, 
skeptical about their still unsatisfactory results, they 
concluded

“Wir wagen kein Raisonnement über das Wie der obigen 
Zerlegungen. Doch scheint uns am meisten natürlich, 
dieselben durch Attraction der Electricität, die sie auf 
gewisse Stoffe, und Repulsion,34 die sie gegen andere 
äußert, zu erklären, ob uns gleich diese Erklärung wenig 
genügend scheint.” (We do not dare upon making any 
reasoning about how the above decompositions are made. 
Yet it seems to us most natural to explain them by the 
attraction of electricity, which it expresses for certain sub-
stances, and repulsion, which it expresses against others, 
although this explanation seems little sufficing to us.)

However, none of the theories proposed thus far had 
been considered as generally valid due to contradictions 
and inconsistencies, and the confusion about the trans-
port of hydrogen and oxygen. The question of the flow of 
the electric current through water during its decomposi-
tion remained. But in 1805, this patchwork of disorien-
tating theories was resolved by the - surprisingly - only 
twenty years old German student Theodor von Grot-
thuß.

33 The concept of the action of a distance, expressed also as the inverse 
square law, applied to Newton’s law of universal gravitation,[59],[60] and to 
Coulomb´s laws for the electrostatic repulsion of equally charged and 
the attraction of oppositely charged points.[61]
34 They relativized on p. 148, footnote 3: “Daß unter Repulsion richtiger 
eine geringere Verwandschaft als eine wirkliche Zurückstoßung zu verste-
hen sey, wird man leicht einsehen”. (It will be easy to see that by rejection 
it is more correct to mean a lesser relationship than an actual rejection.)

2.3 1805: C. J. T. von Grotthuß´ theory of the electropho-
retic current during the electrolysis of water and of the bod-
ies which it holds in solution

During his stay as a student of natural sciences in 
Italy from 1804, baron Christian Johann Dietrich Theo-
dor von Grotthuss (also C. J. Théodore de Grotthuss)35 
formulated a theory that made him highly recognized, 
in particular that of the flow of electricity during the 
decomposition of water. His theory was so plausible 
to his contemporaries that, unlike the ones discussed 
above, it found general acceptance. It was compelling 

35 Christian Johann Dietrich Theodor von Grotthuß (1785, Leipzig, Ger-
many - 1822, Geddutz (at present day Gedučiai), Lithuania. See his por-
trait in Figure 4), member of a German-Baltic noble lineage, began his 
university studies in Leipzig in 1803, and continued six months later at 
École Polytechnique in Paris, then from 1804 in Italy. He left Italy in 1806 
and returned via Paris, Munich and Vienna in 1898 to his manor Ged-
dutz in Courland. Since his return to his manor von Grotthuß tended 
to live secluded from the scientific community. There he continued his 
electrochemical research, and investigated the chemical effect of light.[63]. 
In 1819 he formulated the photochemical absorption law (named Gro-
thuss-Draper law, or the Principle of Photochemical Activation; this law 
was independently formulated in 1842 by the English-born American 
scientist John William Draper). (for details, see e.g. ref. [64]).

Figure 4. Portrait of baron Christian Johann Dietrich Theodor von 
Grotthuß (C. J. Théodore de Grotthuss). Photogravure by Meisen-
bach and Riffart & Co. in Leipzig, produced prior to 1894, undated.



107Capillary Electrophoresis and its Basic Principles in Historical Retrospect.

because it could provide an answer to the previous ques-
tion how hydrogen or oxygen can traverse water in the 
form of a gas from one pole to the other.[65-67]

In Chapter II of “Mémoire sur la decomposition de 
l’eau et des corps qu’elle tient en dissolution à l’aide de 
l’ électricité galvanique” which Grotthuß published in 
1805 in Rome,[65] and in 1806 in Ann. Chim. in Paris,[67] 
he postulated that in each water molecule – he assumed 
that it was made of (HO) – the hydrogen and the oxy-
gen atom are positively and negatively polarized, respec-
tively.36 Upon application of an electric potential the 
molecules orient themselves with their polarized atoms 
in direction of the oppositely electrified poles, forming 
a chain in the liquid in this way, schematically depicted 
by ((+)H-O(-))((+)H-O(-)). In §. 20. of his treatise, he formu-
lated his basic idea as follows

“Il est clair que, dans toute cette opération, les molé-
cules d`eau situeés aux extrêmités des fils conducteurs, 
seront seules décomposées, tandisque toutes celles pla-
cées intermédiairement, échangeront réciproquement et 
alternativement leurs principes composans , san chan-
ger de nature. J`en déduis que, s̀ il était possible d`éta-
blir un courant d`électricité galvanique dans de l èau, de 
façon qù il décrivit dans celle-ci une ligne parfaitement 
circulaire, toutes les molécules du liquide situées dans 
ce cercle, seraient decomposées, et a l`instant recompo-
sées: d`où il suit que cette eau , quoique subissant l èffet 
de l`action galvanique, resterait toujours eau.” (It is clear 
that, throughout this operation, only the water molecules 
located at the tip of the conducting wires will be decom-
posed, whereas all those located at intermediate positions 
will exchange their composing principles reciprocally and 
alternatively, without changing their nature. From this 
I deduce that if it were possible to apply a galvanic cur-
rent in water such that it follows a perfectly circular line, 
all the water molecules of the liquid located in this circle 
would be decomposed and instantly recomposed: whence 
it follows that this water, although subjected to the effect 
of galvanic action, will always remain water.)37

In Figure 5 the scheme of the mechanism of the flow 
of the electrophoretic current during the decomposition 
of water is depicted.

The U-shaped tube (“Fig.1er”) is filled with water into 
which two poles connected to a voltaic pile are dipped. 
The water molecules are pictured as a series of circles 
with positive and negative charges, which is the styl-
ized way of depicting von Grotthuß´ real conception of 
a chain or row of polarized ((+)H-O(-)) molecules but does 

36 In his next paper dated 1807[68]. he depicted the water molecule as 
composed of one hydrogen and two oxygen, what he repeated in his 
work from 1811,[69]. and from 1818.[70]
37 The English version is published in ref. [71].

not display a sequence of ions since Grotthuß refused 
the presence of free ions from water. He believed that 
an ion is always associated with its oppositely charged 
ion. 38 According to his theory, each of the elements of a 
molecule is subject to an attractive and a repulsive force, 
acting in contrary directions. The negative pole attracts 
the positively polarized hydrogen atom and repels the 
negatively polarized oxygen of the water molecules, the 
positive pole accordingly attracts oxygen and repels 
hydrogen.39 These electric forces are sufficiently energetic 
to overcome the chemical affinity in the terminal water 
molecules (that is to say, only in those at the ends of the 
chain). Considering for example hydrogen Q at the end 
of the circular line (positive Q of the water molecule 
QP at the negative pole in Figure 5), decomposition of 
molecule QP occurs, because it gives up its hydrogen Q, 
which is in direct contact with the pole, to the electricity 
of the negative wire. But at the same time as hydrogen 
atom Q is liberated to hydrogen gas, the chain is instan-
taneously (“à l`instant”) re-hydrogenated by hydrogen 

38 Comment of the author: In the fourth circle .after the minus pole of 
the tube in “Fig. 1” a minus should be inserted, not a plus; In the Eng-
lish translation of this paper in Phil. Mag. from 1806 this error was cor-
rected, see Plate IX, Fig. 1 in ref. [66].
39 Although Grotthuß initially assumed that the forces follow the 
inverse square law according to the action at a distance, he nevertheless 
believed that the atoms move with constant velocity, what is a contra-
diction in itself.

Figure 5. Schematic drawing illustrating Grotthuß´ concept of the 
flow of the electric current during the electrolysis of water. “Fig.1re” 
shows a U-tube filled with water, which forms of a chain of posi-
tively polarized hydrogen and negatively polarized oxygen atoms. 
It is important to realize that the circles with + and – signs are 
not ions, they are schematic depictions of the polarized atoms of 
the intact, neutral water molecules (which consist here from one 
hydrogen and one oxygen). During the complete process, free ions 
are not present in water.38 For a more detailed explanation see text. 
Taken from ref. [67].



108 Ernst Kenndler

X of the adjacent molecule, a transfer which occurs in 
the same moment. Oxygen reacts analogue at the posi-
tive pole. It is decisive that only those atoms of the water 
molecules are segregated which are in direct contact 
with the poles. All other water molecules, which are 
between the poles, only exchange their atoms recipro-
cally, but do not change their nature. On these grounds, 
the flow of the electric current is caused by both kinds 
of atoms which continuously travel in opposite direction 
within the aligned chain of water molecules between the 
terminal atoms, forming an electrophoretic current in 
this way. The crucial fact of the matter is that ions are 
never present in their free form, because upon disinte-
gration of the molecules the atoms bind immediately 
to the partner atoms of the next following molecules. 
Hence, all molecules in the solution are subject to the 
permanent and instantaneous process of decomposition 
and recomposition.40

It must be noted that Grotthuß initially assumed, 
but later withdrew, that the force of attraction or repul-
sion follows the action at a distance as Davy and Berze-
lius did. Yet, it is of paramount importance that Grot-
thuss’ theory gave an answer to the apparently paradox 
effect of the evolvement of hydrogen and oxygen at the 
separate poles, because in his theory the evolved gaseous 
elements of water do not originate from the same water 
molecule and therefore do not travers the liquid. Grot-
thuß´ theory was widely accepted41 but - to his annoy-
ance - was initially attributed to the famous scientists 
Davy and Berzelius, and not to the unknown young 
German student. It took about fifteen years until Grot-
thuß asserted his priority on the theory in Volume 1 of 
his book entitled “Physisch-chemische Forschungen”,[28] 
which he published in 1820, and in which he had collect-
ed his main scientific papers (Volume 2 did not appear 
anymore). This book can be regarded as his scientific 
testament, since two years later he committed suicide.

In the introductory commentary of his article from 
1805 which he translated into German by himself in 

40 The German translation and comments were published in 1808 by 
Johann Salomo Christoph Schweigger, professor of philosophy, physics 
and chemistry, and editor of Journal für Chemie und Physik.[72]
41 The author points out the following inconsistency in Grotthuß´ 
description of his theory: according to this theory, negative oxygen P 
combines after the release of positive hydrogen Q with neighboring pos-
itive hydrogen X under formation of the new molecule ((+)P-X(-)). In this 
configuration, the negative oxygen P is that atom which is closest to the 
surface of the – pole. To get into the proper position the molecule has 
to rotate by 180° to ((+)X-P(-)) in order to re-position hydrogen X onto 
the surface of the – pole. These rotations apply to all molecules in the 
chain. Grotthuß´ did not mention this necessity. Faraday pointed to this 
fact when he explained that ice as ordinary insulating dielectric cannot 
be electrolyzed, whereas liquid water can (Experimental Researches in 
Electricity - Fourteenth Series, 1839; 1705.)[73],[74]

“Physisch-chemische Forschungen” Grotthuß wrote some-
what embittered (ref. [75], pp. 113-115):

“Meine (…) Theorie ist später von Davy (…). und von 
Berzelius (…) ohne meiner zu gedenken, weiter verbrei-
tet und (…) jetzt von allen Chemikern (…) angenommen 
worden; nur muß ich bedauern, daß viele von ihnen, 
wiewohl fälschlich, nicht mir, sondern den beiden letzt-
genannten Chemikern diese Theorie zuschreiben die ich 
jedoch weit früher aufgestellt (…) habe42, (…) Nachfol-
gender Aufsatz wurde von mir 1805 in Neapel entworfen, 
und noch in demselben Jahre in Rom gedruckt. (…) daß 
diese Grundidee von mir ein ganzes Jahr (…) früher als 
Davy (…) aufgestellt worden ist, brauch ich wohl kaum 
noch hinzuzufügen. Diesen 1805 in Rom in französischer 
Sprache gedruckten Aufsatz43 sandte ich an Fourcroy 
nach Paris und dieser ließ ihn einige Monate später näm-
lich im April 1806 in den Annales de Chimie aufs neue 
abdrucken,44 Davys obenangeführte Abhandlung betref-
fend, über einige chemische Wirkungen der Electricität 
wurde erst am 20. November 1806 von ihm in der königl. 
Gesellschaft zu London vorgelesen und erschien erst 1807 
in den Transact. philos.45 gedruckt.” (My (…) theory was 
later disseminated by Davy (…) and Berzelius (…) without 
further commemorating me, and is now accepted (…) by 
all chemists; but I must regret that many of them, albeit 
falsely, attribute this theory not to me, but to the latter 
two chemists, though I have it established much earlier, 
(…) The following essay was drafted by me in Naples in 
1805, and printed in Rome the same year (…). I hardly 
need to add that this basic idea was put forward by me a 
whole year (…) earlier than Davy. I sent this essay, printed 
in French in 1805 in Rome, (…) to Fourcroy in Paris, and 
a few months later, in April 1806, he reprinted it anew in 
the Annales de Chimie. Davy’s above-mentioned essay 
about some chemical effects of electricity was read only 
on November 20, 1806 by him at the Royal Society in 
London and appeared printed not until 1807 in the Trans-
act. philos.). [Citations added by the author]. 

In this complaint Grotthuß referred to Davy ś cel-
ebrated Bakerian lecture,46 read on November 20, 1806, 
entitled “On Some Chemical Agencies of Electricity” (ref. 
[62], p.29).

Yet in Chapter I of Grotthuss´ aforementioned 
paper[67] the subject was the “Action of Galvanic Electricity 
upon certain Bodies dissolved in Water”, p. 330-334 in the 
English version[66]). In this theory, “metallic” solutions47 

42 See e.g. ref. [76], p. 691.
43 See ref. [65].
44 See ref. [67].
45 Ref. [62].
46 The Bakerian Medal and Lecture is awarded annually by the Royal 
Society and was established in 1775 by Henry Baker. Humphry Davy 
was awarded the medal every year between 1806 and 1811, and then in 
1826.
47 Meant were solutions of metal salts or metal oxides.



109Capillary Electrophoresis and its Basic Principles in Historical Retrospect.

form a chain of charged particles in the same way as water, 
which move electrophoretically towards their respective 
electrodes. Grotthuß wrote (on p. 338 of ref. [66])

“X XIV. The polar arrangement, such as exists in the 
elementary molecules of water traversed by the Galvan-
ic current, ought to be established equally among the 
elementary molecules of every other liquid body, pro-
vided they are solicited by the same forces. In the metal-
lic solutions the electric polarity takes place among the 
elements of the oxide, the oxygen of which passes to the 
positive pole, and the metal of it is deposited at the neg-
ative pole.”

Grotthuß observed that with certain salts “the mol-
ecules of the metal in solution are revived, assuming a 
symmetrical arrangement, which extends in the direction 
of the galvanic current.” This symmetrical arrangement 
mimicked the shape of leaves of ferns, or of trees with 
limbs and twigs; its generation was therefore named 
arborisation.48 The metal trees grew continuously larger 
at the negative pole, but hydrogen was never formed 
as gas there during the galvanic action. Quite remark-
ably, Grotthuß stated that the arboreal growth from 
the negative toward the positive pole was always in the 
direction of the current. He took this fact as evidence of 
the correctness of his theory regarding water which he 
described in Chapter II of his paper.

2.4 November 1806: Humphry Davy´s Bakerian Lectures, 
catalysts for resurgence of research in galvanic electricity in 
Britain after a four-years hiatus

After a gap of four years since his last publications 
on galvanic electricity in 1802, Humphry Davy pre-
sented the results of his recent investigations in his cel-
ebrated Bakerian lectures, read November, 1806,49[62] 
and November, 1807.[78] Davy reported the results of his 
numerous elaborate experiments with galvanic electric-
ity under various experimental conditions, and with a 
large number of compounds. With respect to the action 
of the galvanic electricity on water Davy presumed (in 
the same manner as Grotthuß) that the constituents of 
water, hydrogen and oxygen, are positively and nega-

48 Arborisation of metals without electricity had already been executed 
by alchemists. By galvanic electricity it was described first in 1800 by 
Cruickshank with silver trees (arbor Dianae),[11]. in 1800 by Brugnatelli 
(published in Annali di Chimica, 1800, T. XVIII, p. 136; excerpt in ref. 
[45]., in 1801 by Gruner as dendrites of silver from silver salt solutions 
(ref. [37], pp. 216-227.) and in 1805 by Ritter as tree of lead dendrites.[77]
49 It was the same Bakerian lecture that was discussed in the previous 
Section, which dealt with the decomposition of water; now the focus is 
to that of salts, acids and bases.[62]

tively polarized (electropositive and electronegative), 
and form a conducting chain. Davy assumed that upon 
completing the electric circuit oxygen and hydrogen 
are attracted by or repelled from the electrified metallic 
surfaces of the oppositely charged poles, and the elec-
tric forces follow the action at a distance. Water is split 
into its elements when its chemical affinity in the mol-
ecule is overcome by electrical forces. The energies of 
the particles which are electrophoretically moving are 
transferred from one particle to the “immediate neigh-
boring particle of the same kind”, which causes the rows 
of both elements to move towards their respective poles. 
At this point, note that each relocated particle is imme-
diately substituted by that behind, and the water remains 
unchanged within the internal volume. This brings Davy 
to the point to state

“In the cases of the separation of the constituents of 
water, (…..) forming the whole of the chain, there may 
possibly be a succession of decompositions and recompo-
sitions throughout the fluid.”

and he continued, referring to a neutral point, which is 
characteristic for the action at a distance

“It is easy to explain, from the general phenomena of 
decomposition and transfer, the mode in which oxygene 
and hydrogene are separately evolved from water. The 
oxygene of a portion of water is attracted by the positive 
surface, at the same time that the other constituent part, 
the hydrogene is repelled by it; and the opposite process 
takes place at the negative surface; and in the middle or 
neutral point of the circuit, whether there be a series of 
decompositions and recompositions, or whether the par-
ticles from the extreme points only are active, there must 
be a new combination of the repelled matter.”

Davy also wondered whether the particles of the 
salts can pass from the one to the opposite pole through 
different “menstrua”, even when they possess a strong-
er attraction to them. An example of an experimental 
arrangement for this question is shown in Figure 6.

In one of these experiments Davy filled dissolved 
muriate of barytes50 into tube A with the positive, and 
distilled water into tube B with the negative pole. First 
he poured muriatic and nitric acid, respectively, into the 
middle tube. Once the circuit was closed, the barytes, 
like most other alkaline substances, passed through the 
acids without any problems, and were transmitted to 
tube B with the negative wire. Vice versa, these acids 

50 Barytes, a term which dates back to late 18th century, is a mineral 
which consists of barium sulphate. In the main text muriate of barytes 
means barium chloride. Muriatic acid is hydrochloric acid.



110 Ernst Kenndler

passed trouble-free electrophoretically through aqueous 
solutions of barytes.51 However, attempts to pass bar-
ytes when sulphuric acid was inserted into the middle 
tube gave a completely different result: after closing the 
circuit, barytes could not be found in the distilled water 
in tube B, but sulphate of baryte precipitated in the mid-
dle tube. The same effect was observed when a solution 
of sulphate of potash52 was in tube B with the negative 
pole of the circuit, a saturated solution of barytes in the 
middle tube, and distilled water in that with the posi-
tive pole. In this case sulphuric acid could not be found 
in distilled water in tube A after closing the circuit, but 
again sulphate of baryte precipitated in the intermedi-
ate tube. Due to its insolubility, in both cases this salt 
became excluded from the galvanic action, inhibiting the 
further transmission of baryte to the negative, and of 
sulphate to the positive pole as consequence. This result 
was clear evidence that the electrophoretic current is due 
to the migration of ions through the solution, and is an 
important finding for the subject at hand.

Davy summarized his observations in section “vi. 
Some general Observations on these Phenomena, and on 
the Mode of Decomposition and Transition” commencing 

51 Note that barium chloride and nitrate are well soluble in water, in 
contrast to the sparingly soluble sulphate.
52 Potash is a mixture of water soluble potassium compounds and potas-
sium-containing materials; its main component is potassium carbonate. 
In the present context sulphate of potash stands for potassium sulphate.

with the repetition of the known facts (pp. 28, 29)

“…that hydrogene, the alkaline substances, the metals, 
and certain metallic oxides, are attracted by negatively 
electrified metallic surfaces, and repelled by positively 
electrified metallic surfaces; and contrariwise, that oxy-
gene and acid substances are attracted by positively elec-
trified metallic surfaces, and repelled by negatively elec-
trified metallic surfaces; and these attractive and repulsive 
forces are sufficiently energetic to destroy or suspend the 
usual operation of elective affinity.”

In an attempt to generalize the theory that he had 
put forward about the electrolysis of water and the 
simultaneous electrophoresis of the ions he continued

“It is very natural to suppose, that the repellent and 
attractive energies are communicated from one particle to 
another particle of the same kind, so as to establish a con-
ducting chain in the fluid; and that the locomotion takes 
place in consequence; …”

and he expressed (see Figure 7 and its Legend) that

“solutions of neutral salts forming the whole of the chain, 
there may possibly be a succession of decompositions and 
recompositions throughout the fluid.”

2.5 Theories as of 1807 at the European Continent

In France the chemist Jean René Denis Riffault (1752 
– 1826) and the physicist and mathematician Nicolas 
Maurice Chompré (1750 - 1825) published in 1807, too, 
a theory about the transition of electricity in solutions 
of acids or bases. They hypothesized that two simulta-
neous currents fragment the bodies into their elements 
throughout the solution and not only at the poles. They 
assumed that the flow of the negative electricity col-
lects the acids and transports them to the positive pole, 
and the same happens vice versa with the bases. In their 
opinion the currents were the stronger the closer they 
were to their respective poles.[82, 83]

Jean-Baptiste Biot, the French physician, mathema-
tician, and astronomer, described his somewhat com-
plex theory in 1824 in Chapitre XVII. Effets chimiques 
de l’Appareil voltaïque. pp. 628-651 of his book Précis 
Élémentaire de Physique Expérimentale.[84] Biot assumed 
that the decomposable substance possesses opposite 
electrical states close to the two poles. The fluid is most 
positive at the positive pole, from where its positive 
polarity decreases with increasing distance, and reach-
es neutrality at the indifference point in the middle 
between the poles. From here on, it approaches the neg-

Figure 6. Drawing of Davy´s experimental arrangement for the 
study “On the Passage of Acids, Alkalies, and other Substances 
through various attracting chemical Menstrua, by Means of Elec-
tricity”. It shows three glass tubes with platinum wires as poles in 
the two outer tubes A and B, which communicate with the mid-
dle tube by strips of amianthus C (i.e. a fine silky asbestos), wet-
ted with distilled water. The experiments are described in the text. 
It clearly confirms the migration of ions by electrophoresis. Taken 
from ref. [79].



111Capillary Electrophoresis and its Basic Principles in Historical Retrospect.

ative pole and becomes increasingly negative. When a 
salt particle is disassembled at the negative pole, its acid 
part becomes more negative than the undecomposed 
ones. It is thereby repelled from the pole and increas-
ingly attracted by the positive pole and by the particles 
of the undecomposed positive fluid around this pole. 
In contrast to Davy, Biot assumed that the particle is 
attached to electricity for the duration of the transition 
and is therefore drawn to the pole with the opposite 
charge. Thus, decomposition of the particles happens in 
the portions of the solution close to the poles, but not 
between them.53

The Sw iss chemist Aug uste Ar t hur de la R ive 
(1801, Geneva - 1873, Marseille) published in 1825 a 
theory that dismissed Grotthuß´ and Dav y’s concepts 
of electrophoretic motion through decomposition and 
recombination.[85] de la Rive assumed a combination 

53 Comment of the author: This configuration will most likely not form 
a stable chain because the particles ⊙ and ○ in the vertical rows are 
in direct contact with those of like charge. In addition, the molecules 
would not be arranged parallel in the chain and thus not perpendicu-
lar to the current, but would rotate alternately by 90° and form a chain 
that is arranged as … ⊙○⊙○⊙○ … . The same applies for Berzelius´ 
theory, but not for Grotthuß´.

of the decomposed bodies with the electricity which 
is released from respective poles. Concerning water, 
the electricity from the positive pole unites accord-
ingly with the hydrogen, moves to the negative pole 
where it is decomposed into electricity and hydrogen, 
which is set free as gas. An analogue process takes 
place with the electrified oxygen, which travels from 
the negative pole to the positive one. In contrast to 
Grotthuß´ and Dav y ś theories, in that of de la Rive 
the successive decomposition and recompositions in 
the course of the current does not occur. Decomposi-
tion of the particles happens only at the poles, but no 
recomposition follows.

For completeness we mention the French mathema-
tician Jean Nicolas Pierre Hachette (1769, Mézières - 
1834, Paris). In 1832, in the same year Michael Faraday 
presented his First Series of Experimental Researches in 
Electricity,[86] Hachette assumed the successive decom-
position of water by a magneto-electric current.[87, 88]. 
However, he did not discuss the migration of the decom-
posed parts. He concluded (ref. [87], p. 73) 

“Il résulte de cette experience, 1° qu’il n’est pas néces-
saire, comme on le croyait, que l’action des deux électri-
cités positive et négative, soit simultanée pour la décom-
position chimique de l’eau; 2° que l’action, dont la dis-
continuité n’est qu’instantanée, peut aussi produire cette 
décomposition.” (It results from this experiment, 1°, that 
it is not necessary, as it was believed, that the action of 
the two electricities, positive and negative, be simultane-
ous for the chemical decomposition of water; 2° that the 
action, the discontinuity of which is only instantaneous, 
can also produce this decomposition.)

In any case, tak ing the various theories into 
account, it is remarkable how long Grotthuß´ from 1805 
lasted. Notwithstanding its replacement by Rudolf Clau-
siuś  much better-founded theory in 1857,[89-91] Clausiuś  
theory – which will be discussed in the subsequent Part 
3 of this series – was acknowledged, but largely ignored; 
and that of Grotthuß was accepted almost unchanged 
for eight decades.

Although Grotthuß´ theory is rather a subject of the 
history of electrochemistry, his name is still connected 
at present time to the special mechanism of the electro-
phoretic transport of H+ in aqueous solutions (named 
proton-jumping or proton-hopping). This Grotthuß-
mechanism explains the extraordinarily high ion con-
ductivity and ionic mobility of H+ due to the presence of 
clusters of water molecules and their involvement in H+ 
transfer (see e.g. ref. [92]).

Figure 7. Illustration of Davy´s theory of the electrophoretic migra-
tion of the oppositely charged particles of a neutral salt during elec-
trolysis. P, N: positive and negative poles. ⊙, ○: positiv and negativ 
particles of the neutral salt ○⊙, which forms a conducting chain 
in the solution. Left and right pictures: arrangement prior and after 
closing the circuit. See the main text for details and footnote53 for 
author’s comment. Taken from ref. [80]. Nearly the same scheme is 
depicted by Berzelius to illustrate his similar theory in ref. [81], p. 
278.



112 Ernst Kenndler

3. AS OF 1832: MICHAEL FARADAY´S POINEERING 
CONTRIBUTIONS IN ELECTRICITY

Michael Faraday54, having attended only elementary 
school was given by a fortunate coincidence and on his 
own initiative the position as Sir Humphry Davy ś labo-
ratory assistant in March 1813. This was the beginning 
of his outstanding career.

At first he assisted Davy with chemical experiments, 
and was allowed to carry out some by himself.55 In 1820 
he was fascinated by the discovery of electromagne-
tism by Hans Christian Ørsted 56,[99] and began research 
in this new field, concurrently to his chemical work on 
organic compounds. In autumn of 1821 he discovered 
the electro-magnetic rotation.[100] During 1824 and 1826 
he attempted, to “convert magnetism into electricity“, but 
without success.[101] After a break until 1831 he returned 
to investigate electromagnetic phenomena and to elec-
tricity. In this year he made the important discovery of 
the electromagnetic induction.[86]

3.1 Faraday´s Series of “Experimental Researches in Elec-
tricity”

From 1832 to 1834 Faraday published eight com-
prehensive papers of the series entitled “Experimental 
Researches in Electricity”. In this series Faraday commu-
nicated the results of his pioneering research on electro-
magnetism, magneto-electric induction, electricity and 
electrolysis in Phil. Trans.[10, 86, 102-107] After his investiga-
tions of electromagnetism in 1831 and 1832 he focused 
his research on electrical and electrochemical topics. The 
“new law of electric conduction” was published in 1833 
in the Fourth Series of Experimental Researches in Elec-
tricity,[104, 108] and aroused his interest in electrochemi-
cal decomposition. Although Faraday is better known 

54 Michael Faraday was born in 1791 in Newington Butts, now part of 
London, and died in 1867. Instead of going into details of Faraday´s 
biography, We refer to a recently published paper by F. Bagnoli and R. 
Livi in this journal.[93]. In their publication the scientific focus is not on 
the migration of ions by electrophoresis. We have avoided duplicating 
information, although in some cases it was is inevitable, for example in 
definitions or in verbatim reproductions of Faraday’s statements.
55 Faraday’s first scientific publication which he was allowed to pub-
lish as laboratory assistant by his own name was about “Analysis of the 
native caustic Lime” and appeared in 1816 in Vol. I of The Journal of the 
Science and of the Arts, later named The Quarterly Journal of Science, 
Literature, and the Arts.[94]. The subsequent experiments dealt espe-
cially with compounds from chlorine and carbon, and the isolation of 
“bi-carburate of hydogen” (i.e. benzene) and other arenes (see e.g. refs. 
[95],[96],[97],[98]).
56 Hans Christian Ørsted (in German Hans Christian Oersted; 1777, 
Rodkøbing – 1851, Copenhagen) was a Danish physicist, chemist and 
nature-philosopher. He was a friend of Johann Wilhelm Ritter.

for his work on electrolysis - where he derived the laws 
named after him - his theories about the motion of ions, 
which superseded those put forward so far, cannot be 
emphasized enough. Hence, Faraday evaluated and crit-
icized these theories in the Fifth Series,[105, 109] § 11. On 
Electro-chemical Decomposition, read June 20, 1833, 481. 
- 491.)57, and presented his own conclusions.

That being said, Faraday published numerous 
important contributions in many scientific fields, but 
in this review only those will be discussed which had a 
closer connection to the present topic. It is mentioned 
that these contributions do not necessarily follow a 
chronologic order in this text. They are, nevertheless, 
dealing with the migration of ions in solution in direc-
tion of lines of electric force, in accordance with the 
definition of electrophoresis given above. Note that Fara-
day coined two new key terms (in the previous sentence 
marked in Italic): ion and lines of electric force. We take 
thus the occasion to begin with Faraday’s proposal of a 
new, unified terminology, which replaced the earlier less 
systematic one, und will end this review with Faraday s̀ 
groundbreaking theory of the lines of electric force, 
also the electric lines of force, the basis of James Clerk 
Maxwell ś field theory.

3.1.1 Faraday`s recommendation for a defined terminology

In the preliminary of his Bakerian lecture in which 
Faraday summarized his results in the Seventh Series[10] he 
pointed to the confusing and arbitrary denotations applied 
thus far in electro-decomposition issues and recommend-
ed their replacement by a consistent and well-defined ter-
minology.58 For this purpose, he suggested to use artificial 
words, constructs of ancient Greece words, viz. by replac-
ing the term pole by electrode, and to distinguish between 
anode and cathode. He also suggested the terms ion, anion, 
cation, electrolyte, electrode, and electrolyze.59

57 The numbers, here 481. and 491., are those of the sub-sections of the 
paragraphs which subdivide the entire Series.
58 Although Berzelius opposed against it, meaning: “Faraday glaubt, ... 
daß unsere gewöhnlichen Wissenschafts – Benennungen … unzureichend 
werden; daher hat er andere eingeführt, von denen ich aber nicht glau-
be, weder daß sie in irgend einer Hinsicht nothwendig waren, noch daß 
sie befolgt zu werden verdienen.“ (ref. [110], pp. 37,38) (Faraday believes 
... that our common scientific designations ... are becoming inadequate; 
hence he introduced others, but I do not believe that they were necessary 
in any way or that they deserve to be obeyed.)
59 One might wonder about the reason why Faraday did not introduce 
the term electrophoresis (greek ἤλεκτρον and φόρεσις (phóresis) “the 
act of bearing”, means thus “the act of bearing electricity”). Probably 
he avoided its use because the simple and common device for the gen-
eration of electricity, the “electrophorus” was still widely known since 
Volt´s time (see Part 1 of this series).[1]. But the author must confess 
that he did not search for an according text passage, neither in the six 



113Capillary Electrophoresis and its Basic Principles in Historical Retrospect.

Since the historical background of the creation of 
this new terms was already briefly discussed in a previ-
ous issue of this journal,[93] we will not go further into 
the details of their origin. Yet, it is remarkable that it is 
still standard nomenclature even today, about two centu-
ries after Faraday ś recommendation.

3.1.2 The inextricable connection of electrolysis and the 
electrophoretic current

A central point in Faraday ś theories was the co-
occurrence of electrolysis and the electrophoretic cur-
rent. He considered the two phenomena as being so 
inseparable, “that one cannot happen without the other”. 
The importance of this connection for Faraday becomes 
clear as he repeated his conviction in various formula-
tions (see § 13 of the Seventh Series,[10] and the Eighth 
Series[107], p. 436), which read, for example

“854. On the other hand, the relation between the con-
duction of the electricity and the decomposition of the 
water is so close, that one cannot take place without the 
other. … 
855. Considering this close and twofold relation, namely, 
that without decomposition transmission of electricity 
does not occur...... 
858. Those bodies which, being interposed between the 
metals of the voltaic pile, render it active, are all of them 
electrolytes (476.); and it cannot but press upon the atten-
tion of every one engaged in considering this subject, that 
in those bodies (so essential to the pile) decomposition 
and the transmission of a current are so intimately con-
nected, that one cannot happen without the other. … 
923. … An electrolyte is always a compound body: it 
can conduct, but only whilst decomposing. Its conduc-
tion depends upon its decomposition and the transmis-
sion of its particles in directions parallel to the current; 
and so intimate is this connexion, that if their transition 
be stopped, the current is stopped also; if their course be 
changed, its course and direction changes with them; …”

In these statements the flow of charge carried by 
ions is phrased as “conduction of electricity, transmission 
of electricity, transmission of a current, transmission of 
its particles, transition [of particles]”, all of which express 
what we name the electrophoretic current.

3.1.3 1833/1834: Faraday´s theory of the electrophoretic 
migration of the ions during electrolysis, and his seminal 
concept of the lines of force

volumes of Faraday´s correspondence,[111]. nor in the seven volumes of 
his diary (the “Experimental Notes”).[112]

The part following the preliminary in the aforesaid 
Seventh Series  in 1834[10] can be seen as the focus of his 
point of view at the motion of ions in solution during 
electrolysis. In this part Faraday reported his experi-
ments of the relation between current and electrochemi-
cally decomposed matter, what he already did in the 
Fifth Series in 1833.[105] One might ask how this relation 
can contribute to the problem of the migration velocity 
of an ion; we detail it as follows.

With reference to the previous theories, the velocity 
of migration is determined by the electrical forces that 
act on the ion by the action at a distance. In this case, 
the electric forces and therefore the migration velocity 
are not constant but vary with the distance between ion 
and electrodes. We recall that electricity was throughout 
considered as a fluid. Over the course of his research, 
Faraday began to doubt these previous theories about 
the continuous character of electricity and the action at 
a distance. It was his unparalleled merit, thanks to his 
studies of electricity and magnetism, to open the win-
dow for a new look at the migration velocity of ions.

3.1.4 The absolute quantity of electricity, a consequence 
of the law of definite electrochemical action

In the Fifth Series Faraday argued “505. That for a con-
stant quantity of electricity, whatever the decomposing con-
ductor may be, … the amount of electro-chemical action is 
also a constant quantity, i.e. would always be equivalent to 
a standard chemical effect founded upon ordinary chemi-
cal affinity”. In the Seventh Series[10] in 1834 he presented 
as conclusion which he derived from the quantitative 
measurements of numerous electrolytically decomposed 
electrolytes the “ law of definite electrochemical action”, or 
the “law of the definite chemical action of electricity” (807.) 
which he expressed in different phrasing, for example as

“732. … with respect to water, that when subjected to the 
influence of the electric current, a quantity of it is decom-
posed exactly proportionate to the quantity of electricity 
which has passed, …
783. The law was expressed thus: The chemical power of a 
current of electricity is in direct proportion to the abso-
lute quantity of electricity which passes.
810. …the results prove that the quantities so decomposed 
are perfectly definite and proportionate to the quantity of 
electricity which has passed.
836. Electro-chemical equivalents coincide, and are the 
same, with ordinary chemical equivalents.”

Note that Faraday accentuated the quantity of elec-
tricity, not its intensity, what he already did in the Third 
Series (ref. [103], 329.).



114 Ernst Kenndler

The forecited extension to quantitative experiments 
enabled Faraday to show that the law of definite electro-
chemical action is generally valid. The electrochemical 
equivalent is a property of a particular ionic species (see 
section vii of the Seventh Series, “On the definite nature 
and extent of Electrochemical Decomposition”).[10] He 
explained that the anions and the cations of an electro-
lyte decompose in portions of electrochemical equiva-
lents, that is to say, in quantities which are given by their 
atomic weigh divided by their charge number. Thus, the 
electrochemical equivalent weight of hydrogen is 1, that 
of oxygen is 16/2 = 8, etc. (p. 111).

Because of the law of definite electrochemical action 
Faraday came to his fundamental conclusion that “an 
absolute quantity of electricity associated with the parti-
cles or atoms of matter” exists (§13). He wrote

“852. The theory of definite electrolytical or electro-chem-
ical action appears to me to touch immediately upon the 
absolute quantity of electricity or electric power belonging 
to different bodies. …, yet there is an immensity of facts 
which justify us in believing that the atoms of matter are 
in someway endowed or associated with electrical pow-
ers, to which they owe their most striking qualities, and 
amongst them their mutual chemical affinity.”

From this insight Faraday derived that electricity con-
sists of fundamental quantities. Ions are therefore always 
charged by one or integer multiples of this charge unit.60

3.1.5 Faraday`s rejection of the action at a distance

Faraday contradicted especially the established con-
cept of the action at a distance, the inverse square law. 
One might remember that Grotthuß formulated in §. 18. 
of his original paper from 1805[65] this action at a dis-
tance concept in regard of the transport of the charged 
particles in water as follows:

“§. 18. L’action de chaque force par rapport à une molécule 
d’eau située sur la route du courant galvanque, est en raison 
inverse du quarré de la distance à laquelle elle s’ exerce.”61

60 It may appear questionable to the reader that we are discussing prop-
erties that seem to be only relevant in electrolysis. However, since the 
migration velocity of an ion depends on its charge, the findings just dis-
cussed are of outmost importance for electrophoresis.
61 Grotthuß` own translation into German in his book from 1820 reads: 
“§. 18. Der Einfluß einer jeden Kraft hinsichtlich auf ein Teilchen Wassers, 
welches in der Richtung des galvanischen Stromes liegt; wirkt umgekehrt 
wie das Quadrat der Entfernung in welcher sie sich äussert“ (ref. [28]., p. 
122). In the English version published in Phil. Mag. it was translated as: 
“XVIII. The action of each force, in respect to a molecule of water situat-
ed in the direction of the Galvanic current, is in the inverse ratio of the 
square of the distance to which it exercises its influence.” (ref. [66], p. 335).

From his magneto-electric investigations Faraday 
realized that this action at a distance does not apply, and 
this previous concept was false. Fortuitously, this part 
of Grotthuß´ theory was already withdrawn by himself 
in 1820, about one decade prior to Faraday’s criticism. 
Most probably Faraday did not have knowledge of Grot-
thuß´ comments in the German translation of his arti-
cle, which he published in his book “Physisch-chemische 
Forschungen” (this book is quoted above)[28]. Grotthuß 
added (in §. 18, p.122)

“Die Annahme daß die Polarelectricität (Ga lvanis-
mus) umgekehrt wie das Quadrat der Entfemung wirke, 
ist grundlos und nicht einmal ganz zuverlässig für die 
gewöhnliche Electricität erwiesen (M, s. Simon im 28sten 
Bde. von Gilberts Annalen62). Daher hätte dieser Para-
graph füglich wegbleiben können.” (The assumption that 
the polar electricity (galvanism) is inverse of the square of 
the distance is proved groundless and not even completely 
reliable for the ordinary electricity (M, see Simon in the 
28th volume of Gilbert’s Annals). Therefore, this para-
graph could have stayed off.)

3.1.6 The migration of ions and the electric lines of force

Already in the Fifth Series, § 11, iii., “Theory of Elec-
trochemical Decomposition”,[105] read a few months prior 

62 Ref. [113], specified by the author.

Figure 8. Drawing which illustrates Michael Faraday´s concept 
of the electrophoretic migration of the ions during electrolysis. In 
the upper scheme anions a and a´ migrate towards the anode, P, 
cations b and b´ to the cathode, N. They are moving parallel to the 
lines of forces, which fill the space between the two electrodes. For 
details, see main text, quoted sub-section 519. in Faraday´s Fifth 
Series. Taken from ref .109.



115Capillary Electrophoresis and its Basic Principles in Historical Retrospect.

to the Seventh Series,[10] Faraday described his view at the 
migration of ions. In his opinion, “the two elementary 
electric currents, moving in opposite directions, from pole 
to pole, constitute the ordinary voltaic current.”63 He stat-
ed that the influence that is present in the electric cur-
rent has to be strictly devised as “an axis of power having 
contrary forces, exactly equal in amount, in contrary direc-
tions.” (517.). This theory was in clear contradiction to the 
earlier established concept of the action at a distance and 
the point of indifference or neutrality and marked a fun-
damental change in the principles of ion migration.

Faraday considered the decomposing bodies as a 
mass of particles, which contribute to the final effect giv-
en that they are in the course of the electric current. The 
effect of the electrochemical decomposition is based on 
an internal corpuscular action, which originates from a 
force, that either adds to the common chemical affinity, 
or determines its direction. The combining particles pass 
in opposite directions because the usual chemical affin-
ity is reduced, weakened or partially neutralized by the 
influence of the electric current in one direction paral-
lel to its course, and reinforced or supplemented in the 
opposite direction. The author comments that this is in 
fact the description of the electrophoretic motion.

Faraday expounded his theory again in section 519. 
of the Fifth Series (ref.[105], p. 696¸ German translation 
ref. [109]) explaining (see Figure 8).64

“519. In this view the effect is considered as essentially 
dependent upon the mutual chemical affinity of the par-
ticles of opposite kinds. Particles a a, fig. 7, could not be 
transferred or travel from one pole N towards the other P, 
unless they found particles of the opposite kind b b, ready 
to pass in the contrary direction: for it is by virtue of 
their increased affinity for those particles, combined with 
their diminished affinity for such as are behind them in 
their course, that they are urged forward: and when any 
one particle a, fig. 8, arrives at the pole, it is excluded or 
set free, because the particle b of the opposite kind, with 
which it was the moment before in combination, has, 
under the superinducing influence of the current, a great-
er attraction for the particle a ,́ which is before it in its 
course, than for the particle a, towards which its affinity 
has been weakened.”

Consequently, all composite particles in the course of 
the current act conjointly, except those which are in con-

63 This attribution deviates from ours, because the ordinary voltaic current 
is the flow of electrons (electrons were unknown at the time). In contrast, 
“the two elementary electrical currents that move from pole to pole in oppo-
site directions” is the flow of charge carried by ions in solution. It is the 
current for which we coined the term electrophoretic current.
64 The collection of all 14 Series of the Experimental Researches in Electric-
ity, reprinted from the Phil. Trans. of 1831 – 1838 is published in ref. [73].

tact with the poles. They “consist of elementary particles, 
which, whilst they are in one direction expelling, are in the 
other being expelled”. The acting particles (i.e. the ions) 
which represent the electric current move in direction of 
the electric lines of action or lines of electric force. Like 
the lines of magnetic force65 the electric lines do not nec-
essarily form a straight line between the electrodes, nei-
ther must they be parallel, but they do not cross.66

Due to its importance, we repeat the explanation 
of the line of force which Faraday gave about one dec-
ade later, viz. in the Nineteenth Series, read in November 
1845.[114] He stated

“:—thus, by line of magnetic force, or magnetic line of 
force, or magnetic curve, I mean that exercise of magnetic 
force which is exerted in the lines usually called mag-
netic curves, and which equally exist as passing from or 
to magnetic poles, or forming concentric circles round an 
electric current. By line of electric force, I mean the force 
exerted in the lines joining two bodies, acting on each 
other according to the principles of static electric induc-
tion, which may also be either in curved or straight lines.”

3.1.7 The migration velocity of the ions and its assumed 
context with the decomposition of equal chemical equi-
valents of anions and cations

Faraday’s replacement of the earlier theory of the 
action at a distance by that of the electric lines of force67 
and the conclusion of an elementary charge unit had far-
reaching consequences for the question of the migration 
velocity of the ions. In the earlier concept of the action 
at a distance this electric force acting on an ion varied 
with the in the inverse ratio of the square of the distance 
from the electrodes, and consequently its drift velocity 
varied as well. In Faraday ś theory, the velocity in the 
electric field, in contrast, is constant during the motion 
of the ion along a field line.68 That is to say, in a homo-

65 In the First Series of Experimental Researches in Electricity, read 
November 1831, Faraday reported the induction of electric currents 
and the generation of electricity from magnetism. In this paper, Fara-
day defined for the first time the lines of force as ”By magnetic curves, I 
mean the lines of magnetic forces, however modified by the juxtaposition 
of poles, which would be depicted by iron filings; or those to which a very 
small magnetic needle would form a tangent.”(ref. [86],114.; footnote at p. 
154). These magnetic field lines can be visualized by iron files poured 
onto a sheet of paper with a magnet underneath.
66 All these properties apply for all configurations. In a homogeneous 
electric field, for example in the field between two plate electrodes, 
nearly all lines are straight and parallel, and, as all others in all configu-
rations, are perpendicular to the surfaces of the plates.
67 Ref. [114], 2149., and ref. [115],1662.
68 To emphasize the importance of Faraday´s theory of the lines of elec-
tric force for electrophoresis, and his conclusion that ions carry elemen-
tary charge units, we skip a period in the development of the theory of 



116 Ernst Kenndler

geneous field ions migrate with an equal and constant 
velocity along the field lines that run parallel to one 
another. Faraday brought forward this argument in the 
Eighth Series read June 1834,[107] p. 448, that

“964. … If any number of them [anions and cations] enter 
as ions into the constitution of electrolytes, and, form-
ing one circuit, are simultaneously subject to one com-
mon current, the anions must move in accordance with 
each other in one direction, and the cations in the other. 
Nay, more than that, equivalent portions of these bodies 
must so advance in opposite directions; for the advance of 
every 32*5 parts of the zinc … must be accompanied by a 
motion in the opposite direction of 8 parts of oxygen … 
of 36 parts of chlorine … , of 126 parts of iodine … ; and 
in the same direction by electro-chemical equivalents of 
hydrogen, … lead, copper and tin, …”

It can be seen that Faraday based his conclusion 
on the opposite movement of equal electrochemical 
equivalents of cations and anions of an electrolyte to 
their respective electrodes during electrolysis. In the 
simplest case the electrolyte consists of two ions with 
a single charge each. Then, an anion cannot be oxi-
dized on the anode unless a cation is reduced at the 
same time on the cathode. Due to the requirement to 
reach their electrodes at the same time Faraday con-
cluded that the migration velocities of cations and ani-
ons must also be equal. Faraday did not provide any 
values for this velocity. On the top of that, it will be 
seen later that his hypothesis was based on a mistake 
in reasoning.

The first systematic attempts to measure the values 
of the drift velocity were made by Wilhelm Hittorf in 
the 1850s. Yet, Hittorf did not determine the absolute, 
but the relative velocities of the various ion species to 
one another, referred to as transference or transport 
numbers. This topic, and the subsequent studies to 
determine the actual migration velocity of an ion will 
be the subject of the following Part 3 of this historical 
retrospect.

ion migration. Today it is well-known that the electrical force acting on 
an ion is proportional to its charge, z.e, and the strength of the electric 
field, E = U/d. Here z is the number of charges, e the electron charge, U 
the potential difference and d the distance between the electrodes. That 
is, on ions with the same number of charges an equal electrical force is 
acting, independent of its distance from the electrodes. This is in clear 
contradiction to the action at a distance. This force accelerates the ion, 
but the oppositely directed frictional force of the medium increases with 
increasing speed. The frictional force depends on the size and shape of 
the ion and is thus different for different ions. When both forces are 
equal, the ion moves with a constant migration velocity (for the sake of 
simplicity, we have considered an ion at infinite dilution).

4. SUMMARY

By following the general definition that “electropho-
resis is the motion of dispersed particles relative to a fluid 
under the influence of a spatially uniform electric field” 
we have chosen a probably unusual view at electropho-
resis in this Part 2, since the focus is aimed exclusively 
at ions. This view is justified because, as defined above, 
ions of atomic or molecular size are also the subject of 
electrophoresis, not just colloidal particles as is conven-
tionally considered.

Due to the inextricable linkage between ion migra-
tion and electrolysis the histories of these two phenom-
ena are also intrinsically related. It is for this reason that 
this review begins with the year 1800 when electrolysis 
by galvanic electricity - which was considered as a fluid 
at that time - was discovered. It extends over the time 
until the 1830s and early 1840s when Michael Faraday 
superseded the previously established concept of action 
at a distance by that of the electric lines of force, which 
were later referred to as field lines of the electric field.

It is pointed out that during the electrolysis of 
decomposable compounds by galvanic electricity two 
kinds of currents can be differentiated in the closed elec-
tric circuit. The galvanic or voltaic current is the flow of 
charges carried by electrons in the metallic parts (elec-
trons were not known at the time). But decomposition 
can only take place if an electric current flows through 
the liquid from one pole to the other. Although this pro-
cess is obviously invisible to the naked eye, the several 
observations provided evidence that electricity was actu-
ally being transported through the liquid, e.g. due to the 
increased speed of electrolysis at higher concentrations 
of decomposable bodies, the analytic determination of 
parts of the decomposed molecules close to one pole, e.g. 
of potassium at the negatively charged electrode after 
electrolysis of muriate of potash, or by the kind of the 
decomposition products formed at the poles by electroly-
sis For this flow of these charged particles, later named 
ions, between the poles, which is an electric, but not a 
galvanic current, we coin the term electrophoretic cur-
rent. While not common, it fully conforms to the defini-
tion of electrophoresis quoted above.

Taking these facts into account, the history of elec-
trophoresis begins in 1800 with W. Nicholsoń s and A. 
Carlisle ś experiments of decomposing water by the aid 
of a voltaic pile. Remarkably, just two months after their 
publication, as early as in September 1800, the first theo-
ries of the action of galvanic electricity on water were 
presented by W. Cruickshank in Britain and by J. W. Rit-
ter in Germany. Both researchers hypothesized that gase-
ous hydrogen and oxygen, evolving at the separate poles, 



117Capillary Electrophoresis and its Basic Principles in Historical Retrospect.

came from the same water molecule. In the following 
years, not surprising due to the novelty of the phenom-
ena, experiments were carried out mainly for the acquire-
ment of the results of galvanic action on solutions of 
arbitrarily chosen compounds and different experimen-
tal set-ups. In all cases the researchers were convinced 
that the two ions that assemble the decomposable mol-
ecule are tightly bound to each other, and could only be 
separated by the action of galvanic electricity, when the 
electric force from the connected voltaic pile overcame 
their chemical affinity. Davy and Berzelius assumed that 
the ions migrated because they were attracted or repelled 
by the charged poles, whereby the electric forces obeyed 
the action at a distance. That is, the forces decrease in 
the inverse ratio of to the square of the distance from the 
poles and cross at the point of indifference or neutrality. 
The compounds are decomposed near or at this point, 
but the decomposed particles appear at the poles, which 
makes this hypothesis quite difficult to comprehend. The 
action at a distance brought forth that the ions moved 
with varying, but not with constant velocity.

In 1803 Berzelius and W. Hisinger were able to cre-
ate a classification based on the properties of the ions 
involved in electrolytic decomposition and the direction 
of their electrophoretic migration towards their respective 
poles. It was a first step to systematically categorize com-
pounds into electropositive and electronegative classes.

Back in 1800, beginning with Cruickshank and Rit-
ter, several other theories about the electrolytic decom-
position and the electrophoretic current were developed. 
Works up to 1805 include the theory of the Italian L. V. 
Brugnatelli from 1800, who, to his surprise, found that 
the Belgian E.G. Robert (also Robertson and Robert-son) 
had already published almost the same theory before 
him; they report the theories of the French A. F. Four-
croy, L.-N. Vauquelin and L. J. Thénard in 1800 and 
1801, of the German J. F. Erdmann in 1802, of H. Davy, 
who paused after 1802 for four years, and of the Swedes 
W. Hisinger and J. J. Berzelius in 1803.

However, one of the most plausible theories at that 
time, which surprisingly outlasted almost eight dec-
ades, was presented in 1805 by Theodor von Grotthuß 
(also C.J.T. de Grotthuss). He hypothesized that water 
or dissolved salts form a chain of polarized molecules, 
and only the terminal atoms of the chain, which were 
in direct contact with the surfaces of the oppositely 
charged electrodes were set free by galvanic electric-
ity. However, important for electrophoresis is Grotthuß´ 
hypothesis how the current flows through water or salt 
solutions. He assumed that the liberated terminal atoms 
are instantaneously replaced by the neighboring atoms 
of the same species, which led to a permanent decompo-

sition and recombination of the molecules in the chain, 
and to the electric current in this way. 

It was thus believed that free ions were never present 
in the fluid. To his disappointment, the priority of his 
theory was initially assigned to the widely recognized 
scientist Davy, who published a similar theory about one 
year later.

Indeed, in December, 1806 Davy read a celebrated 
Bakerian lecture with a theory in which he also assumed 
a chain of molecules, and a similar process of decompo-
sition and recombination as Grotthuß. After Grotthuß 
and Davy, fewer theories were formulated, e.g. by the 
French J. R. D. Riffault and N. M. Chompré in 1807, and 
after a break of about fifteen years, by the French J.-B. 
Biot in 1824, then by the Swiss A. A. de la Rive in 1825, 
and the French J. N. P. Hachette in 1832.

However, all these theories were dismissed in 1833 
by Michael Faraday, who unambiguously rejected the 
concept of action at a distance. Based on his experience, 
which he had gained from his previous studies of magnet-
ism and electromagnetism, Faraday developed the the-
ory of lines of magnetic and electric force, which served 
James Clerk Maxwell for the mathematical formulation of 
the field theory. This was one of Faraday’s groundbreak-
ing contributions to the further development of electricity 
and electromagnetism and thus to electrophoresis as well 
and opened a new era in these topics. Another major con-
tribution, which he deduced from his law of definite elec-
trochemical action, was his proof that electricity consists 
of individual elementary charge units. The consequence of 
Faraday’s seminal theories was that ions move at constant 
velocities parallel to the lines of the electric force that fill 
the space between the electrodes. Thus, after more than 
three decades the concept of the action at a distance and 
its consequences were superseded. What remained was 
the conviction that electrolyte molecules consist of tightly 
bound ions of opposite charge, which can only be separat-
ed by electrical forces, whereupon they are permanently 
and instantaneously decomposed and recombined form-
ing in this way the electrophoretic current. Accordingly, 
free ions are not present in solutions in the absence of an 
electric field.

However, none of these theories dealt with the magni-
tudes of the velocities of ion migration, and the questions 
whether these speeds are actually equal, how high they are 
and on what conditions they depend, remained open.

ACKNOWLEDGEMENT

The author acknowledges Salvator Kenndler for his 
valuable comments.



118 Ernst Kenndler

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