Received January 9,—Read
January 23, February 6 and 13, 1834.
Preliminary.
661. The theory which I believe
to be a true expression of the facts of electro-chemical
decomposition, and which I have therefore detailed
in a former series of these Researches, is so much
at variance with those previously advanced, that I
find the greatest difficulty in stating results, as
I think, correctly, whilst limited to the use of terms
which are current with a certain accepted meaning.
Of this kind is the term pole, with its prefixes
of positive and negative, and the attached ideas of
attraction and repulsion. The general phraseology
is that the positive pole attracts oxygen,
acids, &c., or more cautiously, that it determines
their evolution upon its surface; and that the negative
pole acts in an equal manner upon hydrogen, combustibles,
metals, and bases. According to my view, the
determining force is not at the poles, but
within the body under decomposition; and the
oxygen and acids are rendered at the negative
extremity of that body, whilst hydrogen, metals, &c.,
are evolved at the positive extremity (518.
524.).
662. To avoid, therefore, confusion
and circumlocution, and for the sake of greater precision
of expression than I can otherwise obtain, I have
deliberately considered the subject with two friends,
and with their assistance and concurrence in framing
them, I purpose henceforward using certain other terms,
which I will now define. The poles, as
they are usually called, are only the doors or ways
by which the electric current passes into and out
of the decomposing body (556.); and they of course,
when in contact with that body, are the limits of its
extent in the direction of the current. The term
has been generally applied to the metal surfaces in
contact with the decomposing substance; but whether
philosophers generally would also apply it to the surfaces
of air (465. 471.) and water (493.), against which
I have effected electro-chemical decomposition, is
subject to doubt. In place of the term pole, I
propose using that of Electrode, and I mean
thereby that substance, or rather surface, whether
of air, water, metal, or any other body, which bounds
the extent of the decomposing matter in the direction
of the electric current.
663. The surfaces at which, according
to common phraseology, the electric current enters
and leaves a decomposing body, are most important places
of action, and require to be distinguished apart from
the poles, with which they are mostly, and the electrodes,
with which they are always, in contact. Wishing
for a natural standard of electric direction to which
I might refer these, expressive of their difference
and at the same time free from all theory, I have
thought it might be found in the earth. If the
magnetism of the earth be due to electric currents
passing round it, the latter must be in a constant
direction, which, according to present usage of speech,
would be from east to west, or, which will strengthen
this help to the memory, that in which the sun appears
to move. If in any case of electro-decomposition
we consider the decomposing body as placed so that
the current passing through it shall be in the same
direction, and parallel to that supposed to exist
in the earth, then the surfaces at which the electricity
is passing into and out of the substance would have
an invariable reference, and exhibit constantly the
same relations of powers. Upon this notion we
purpose calling that towards the east the anode,
and that towards the west the cathode; and
whatever changes may take place in our views of the
nature of electricity and electrical action, as they
must affect the natural standard referred to,
in the same direction, and to an equal amount with
any decomposing substances to which these terms may
at any time be applied, there seems no reason to expect
that they will lead to confusion, or tend in any way
to support false views. The anode is therefore
that surface at which the electric current, according
to our present expression, enters: it is the
negative extremity of the decomposing body;
is where oxygen, chlorine, acids, &c., are evolved;
and is against or opposite the positive electrode.
The cathode is that surface at which the current
leaves the decomposing body, and is its positive
extremity; the combustible bodies, metals, alkalies,
and bases, are evolved there, and it is in contact
with the negative electrode.
664. I shall have occasion in
these Researches, also, to class bodies together according
to certain relations derived from their electrical
actions (822.); and wishing to express those relations
without at the same time involving the expression
of any hypothetical views, I intend using the following
names and terms. Many bodies are decomposed directly
by the electric current, their elements being set
free; these I propose to call electrolytes.
Water, therefore, is an electrolyte. The bodies
which, like nitric or sulphuric acids, are decomposed
in a secondary manner (752. 757.), are not included
under this term. Then for electro-chemically
decomposed, I shall often use the term electrolyzed,
derived in the same way, and implying that the body
spoken of is separated into its components under the
influence of electricity: it is analogous in its
sense and sound to analyse, which is derived
in a similar manner. The term electrolytical
will be understood at once: muriatic acid is
electrolytical, boracic acid is not.
665. Finally, I require a term
to express those bodies which can pass to the electrodes,
or, as they are usually called, the poles. Substances
are frequently spoken of as being electro-negative,
or electro-positive, according as they go under
the supposed influence of a direct attraction to the
positive or negative pole. But these terms are
much too significant for the use to which I should
have to put them; for though the meanings are perhaps
right, they are only hypothetical, and may be wrong;
and then, through a very imperceptible, but still
very dangerous, because continual, influence, they
do great injury to science, by contracting and limiting
the habitual views of those engaged in pursuing it.
I propose to distinguish such bodies by calling those
anions which go to the anode of the
decomposing body; and those passing to the cathode,
cations; and when I have occasion to speak
of these together, I shall call them ions.
Thus the chloride of lead is an electrolyte,
and when electrolyzed evolves the two ions,
chlorine and lead, the former being an anion,
and the latter a cation.
666. These terms being once well-defined,
will, I hope, in their use enable me to avoid much
periphrasis and ambiguity of expression. I do
not mean to press them into service more frequently
than will be required, for I am fully aware that names
are one thing and science another.
667. It will be well understood
that I am giving no opinion respecting the nature
of the electric current now, beyond what I have done
on former occasions (283. 517.); and that though I
speak of the current as proceeding from the parts
which are positive to those which are negative (663.),
it is merely in accordance with the conventional,
though in some degree tacit, agreement entered into
by scientific men, that they may have a constant,
certain, and definite means of referring to the direction
of the forces of that current.
[Since this paper was read, I have
changed some of the terms which were first proposed,
that I might employ only such as were at the same time
simple in their nature, clear in their reference, and
free from hypothesis.
iv. On some general conditions
of Electro-chemical Decomposition.
669. From the period when electro-chemical
decomposition was first effected to the present time,
it has been a remark, that those elements which, in
the ordinary phenomena of chemical affinity, were the
most directly opposed to each other, and combined
with the greatest attractive force, were those which
were the most readily evolved at the opposite extremities
of the decomposing bodies (549.).
670. If this result was evident
when water was supposed to be essential to, and was
present in, almost every case of such decomposition
(472.), it is far more evident now that it has been
shown and proved that water is not necessarily concerned
in the phenomena (474.), and that other bodies much
surpass it in some of the effects supposed to be peculiar
to that substance.
671. Water, from its constitution
and the nature of its elements, and from its frequent
presence in cases of electrolytic action, has hitherto
stood foremost in this respect. Though a compound
formed by very powerful affinity, it yields up its
elements under the influence of a very feeble electric
current; and it is doubtful whether a case of electrolyzation
can occur, where, being present, it is not resolved
into its first principles.
672. The various oxides, chlorides,
iodides, and salts, which I have shown are decomposable
by the electric current when in the liquid state, under
the same general law with water (402.), illustrate
in an equally striking manner the activity, in such
decompositions, of elements directly and powerfully
opposed to each other by their chemical relations.
673. On the other hand, bodies
dependent on weak affinities very rarely give way.
Take, for instance, glasses: many of those formed
of silica, lime, alkali, and oxide of lead, may be
considered as little more than solutions of substances
one in another. If bottle-glass be fused, and
subjected to the voltaic pile, it does not appear to
be at all decomposed (408.). If flint glass,
which contains substances more directly opposed, be
operated upon, it suffers some decomposition; and if
borate of lead glass, which is a definite chemical
compound, be experimented with, it readily yields
up its elements (408.).
674. But the result which is
found to be so striking in the instances quoted is
not at all borne out by reference to other cases where
a similar consequence might have been expected.
It may be said, that my own theory of electro-chemical
decomposition would lead to the expectation that all
compound bodies should give way under the influence
of the electric current with a facility proportionate
to the strength of the affinity by which their elements,
either proximate or ultimate, are combined. I
am not sure that that follows as a consequence of
the theory; but if the objection is supposed to be
one presented by the facts, I have no doubt it will
be removed when we obtain a more intimate acquaintance
with, and precise idea of, the nature of chemical
affinity and the mode of action of an electric current
over it (518. 524.): besides which, it is just
as directly opposed to any other theory of electro-chemical
decomposition as the one I have propounded; for if
it be admitted, as is generally the case, that the
more directly bodies are opposed to each other in
their attractive forces, the more powerfully do they
combine, then the objection applies with equal force
to any of the theories of electrolyzation which have
been considered, and is an addition to those which
I have taken against them.
675. Amongst powerful compounds
which are not decomposed, boracic acids stand prominent
(408.). Then again, the iodide of sulphur, and
the chlorides of sulphur, phosphorus, and carbon,
are not decomposable under common circumstances, though
their elements are of a nature which would lead to
a contrary expectation. Chloride of antimony (402.
690.), the hydro-carbons, acetic acid, ammonia, and
many other bodies undecomposable by the voltaic pile,
would seem to be formed by an affinity sufficiently
strong to indicate that the elements were so far contrasted
in their nature as to sanction the expectation that,
the pile would separate them, especially as in some
cases of mere solution (530. 544.), where the affinity
must by comparison be very weak, separation takes place.
676. It must not be forgotten,
however, that much of this difficulty, and perhaps
the whole, may depend upon the absence of conducting
power, which, preventing the transmission of the current,
prevents of course the effects due to it. All
known compounds being non-conductors when solid, but
conductors when liquid, are decomposed, with perhaps
the single exception at present known of periodide
of mercury (679. 691.); and even water itself,
which so easily yields up its elements when the current
passes, if rendered quite pure, scarcely suffers change,
because it then becomes a very bad conductor.
677. If it should hereafter be
proved that the want of decomposition in those cases
where, from chemical considerations, it might be so
strongly expected (669, 672. 674.), is due to the
absence or deficiency of conducting power, it would
also at the same time be proved that decomposition
depends upon conduction, and not the latter
upon the former (413.); and in water this seems to
be very nearly decided. On the other hand, the
conclusion is almost irresistible, that in electrolytes
the power of transmitting the electricity across the
substance is dependent upon their capability
of suffering decomposition; taking place only whilst
they are decomposing, and being proportionate to the
quantity of elements separated (821.). I may
not, however, stop to discuss this point experimentally
at present.
678. When a compound contains
such elements as are known to pass towards the opposite
extremities of the voltaic pile, still the proportions
in which they are present appear to be intimately
connected with capability in the compound of suffering
or resisting decomposition. Thus, the protochloride
of tin readily conducts, and is decomposed (402.),
but the perchloride neither conducts nor is decomposed
(406.). The protiodide of tin is decomposed when
fluid (402.); the periodide is not (405.). The
periodide of mercury when fused is not decomposed (691.),
even though it does conduct. I was unable to
contrast it with the protiodide, the latter being
converted into mercury and periodide by heat.
679. These important differences
induced me to look more closely to certain binary
compounds, with a view of ascertaining whether a law
regulating the decomposability according to
some relation of the proportionals or equivalents
of the elements, could be discovered. The proto
compounds only, amongst those just referred to, were
decomposable; and on referring to the substances quoted
to illustrate the force and generality of the law
of conduction and decomposition which I discovered
(402.), it will be found that all the oxides, chlorides,
and iodides subject to it, except the chloride of
antimony and the periodide of mercury, (to which may
now perhaps be added corrosive sublimate,) are also
decomposable, whilst many per compounds of the same
elements, not subject to the law, were not so (405.
406.).
680. The substances which appeared
to form the strongest exceptions to this general result
were such bodies as the sulphuric, phosphoric, nitric,
arsenic, and other acids.
681. On experimenting with sulphuric
acid, I found no reason to believe that it was by
itself a conductor of, or decomposable by, electricity,
although I had previously been of that opinion (552.).
When very strong it is a much worse conductor than
if diluted. If then subjected to the action
of a powerful battery, oxygen appears at the anode,
or positive electrode, although much is absorbed (728.),
and hydrogen and sulphur appear at the cathode,
or negative electrode. Now the hydrogen has with
me always been pure, not sulphuretted, and has been
deficient in proportion to the sulphur present, so
that it is evident that when decomposition occurred
water must have been decomposed. I endeavoured
to make the experiment with anhydrous sulphuric acid;
and it appeared to me that, when fused, such acid
was not a conductor, nor decomposed; but I had not
enough of the dry acid in my possession to allow me
to decide the point satisfactorily. My belief
is, that when sulphur appears during the action of
the pile on sulphuric acid, it is the result of a secondary
action, and that the acid itself is not electrolyzable
(757.).
682. Phosphoric acid is, I believe,
also in the same condition; but I have found it impossible
to decide the point, because of the difficulty of
operating on fused anhydrous phosphoric acid.
Phosphoric acid which has once obtained water cannot
be deprived of it by heat alone. When heated,
the hydrated acid volatilizes. Upon subjecting
phosphoric acid, fused upon the ring end of a wire
(401.), to the action of the voltaic apparatus, it
conducted, and was decomposed; but gas, which I believe
to be hydrogen, was always evolved at the negative
electrode, and the wire was not affected as would
have happened had phosphorus been separated. Gas
was also evolved at the positive electrode. From
all the facts, I conclude it was the water and not
the acid which was decomposed.
683. Arsenic acid. This
substance conducted, and was decomposed; but it contained
water, and I was unable at the time to press the investigation
so as to ascertain whether a fusible anhydrous arsenic
acid could be obtained. It forms, therefore,
at present no exception to the general result.
684. Nitrous acid, obtained by
distilling nitrate of lead, and keeping it in contact
with strong sulphuric acid, was found to conduct and
decompose slowly. But on examination there were
strong reasons for believing that water was present,
and that the decomposition and conduction depended
upon it. I endeavoured to prepare a perfectly
anhydrous portion, but could not spare the time required
to procure an unexceptionable result.
685. Nitric acid is a substance
which I believe is not decomposed directly by the
electric current. As I want the facts in illustration
of the distinction existing between primary and secondary
decomposition, I will merely refer to them in this
place (752.).
686. That these mineral acids
should confer facility of conduction and decomposition
on water, is no proof that they are competent to favour
and suffer these actions in themselves. Boracic
acid does the same thing, though not decomposable.
M. de la Rive has pointed out that chlorine has this
power also; but being to us an elementary substance,
it cannot be due to its capability of suffering decomposition.
687. Chloride of sulphur does
not conduct, nor is it decomposed. It consists
of single proportionals of its elements, but is not
on that account an exception to the rule (679.), which
does not affirm that all compounds of single
proportionals of elements are decomposable, but that
such as are decomposable are so constituted.
688. Protochloride of phosphorus
does not conduct nor become decomposed.
689. Protochloride of carbon
does not conduct nor suffer decomposition. In
association with this substance, I submitted the hydro-chloride
of carbon from olefiant gas and chlorine to the
action of the electric current; but it also refused
to conduct or yield up its elements.
600. With regard to the exceptions
(679.), upon closer examination some of them disappear.
Chloride of antimony (a compound of one proportional
of antimony and one and a half of chlorine) of recent
preparation was put into a tube (fi.) (789.),
and submitted when fused to the action of the current,
the positive electrode being of plumbago. No electricity
passed, and no appearance of decomposition was visible
at first; but when the positive and negative electrodes
were brought very near each other in the chloride,
then a feeble action occurred and a feeble current
passed. The effect altogether was so small (although
quite amenable to the law before given (394.)), and
so unlike the decomposition and conduction occurring
in all the other cases, that I attribute it to the
presence of a minute quantity of water, (for which
this and many other chlorides have strong attractions,
producing hydrated chlorides,) or perhaps of a true
protochloride consisting of single proportionals (695,
796.).
691. Periodide of mercury being
examined in the same manner, was found most distinctly
to insulate whilst solid, but conduct when fluid, according
to the law of liquido-conduction (402.); but
there was no appearance of decomposition. No
iodine appeared at the anode, nor mercury or
other substance at the cathode. The case
is, therefore, no exception to the rule, that only
compounds of single proportionals are decomposable;
but it is an exception, and I think the only one,
to the statement, that all bodies subject to the law
of liquido-conduction are decomposable. I
incline, however, to believe, that a portion of protiodide
of mercury is retained dissolved in the periodide,
and that to its slow decomposition the feeble conducting
power is due. Periodide would be formed, as a
secondary result, at the anode; and the mercury
at the cathode would also form, as a secondary
result, protiodide. Both these bodies would mingle
with the fluid mass, and thus no final separation
appear, notwithstanding the continued decomposition.
692. When perchloride of mercury
was subjected to the voltaic current, it did not conduct
in the solid state, but it did conduct when fluid.
I think, also, that in the latter case it was decomposed;
but there are many interfering circumstances which
require examination before a positive conclusion can
be drawn.
693. When the ordinary protoxide
of antimony is subjected to the voltaic current in
a fused state, it also is decomposed, although the
effect from other causes soon ceases (402, 801.).
This oxide consists of one proportional of antimony
and one and a half of oxygen, and is therefore an
exception to the general law assumed. But in working
with this oxide and the chloride, I observed facts
which lead me to doubt whether the compounds usually
called the protoxide and the protochloride do not often
contain other compounds, consisting of single proportions,
which are the true proto compounds, and which, in
the case of the oxide, might give rise to the decomposition
above described.
694. The ordinary sulphuret of
antimony its considered as being the compound with
the smallest quantity of sulphur, and analogous in
its proportions to the ordinary protoxide. But
I find that if it be fused with metallic antimony,
a new sulphuret is formed, containing much more of
the metal than the former, and separating distinctly,
when fused, both from the pure metal on the one hand,
and the ordinary gray sulphuret on the other.
In some rough experiments, the metal thus taken up
by the ordinary sulphuret of antimony was equal to
half the proportion of that previously in the sulphuret,
in which case the new sulphuret would consist of single
proportionals.
695. When this new sulphuret
was dissolved in muriatic acid, although a little
antimony separated, yet it appeared to me that a true
protochloride, consisting of single proportionals,
was formed, and from that by alkalies, &c., a true
protoxide, consisting also of single proportionals,
was obtainable. But I could not stop to ascertain
this matter strictly by analysis.
696. I believe, however, that
there is such an oxide; that it is often present in
variable proportions in what is commonly called protoxide,
throwing uncertainty upon the results of its analysis,
and causing the electrolytic decomposition above described.
697. Upon the whole, it appears
probable that all those binary compounds of elementary
bodies which are capable of being electrolyzed when
fluid, but not whilst solid, according to the law
of liquido-conduction (394.), consist of single
proportionals of their elementary principles; and it
may be because of their departure from this simplicity
of composition, that boracic acid, ammonia, perchlorides,
periodides, and many other direct compounds of elements,
are indecomposable.
698. With regard to salts and
combinations of compound bodies, the same simple relation
does not appear to hold good. I could not decide
this by bisulphates of the alkalies, for as long as
the second proportion of acid remained, water was
retained with it. The fused salts conducted, and
were decomposed; but hydrogen always appeared at the
negative electrode.
699. A biphosphate of soda was
prepared by heating, and ultimately fusing, the ammonia-phosphate
of soda. In this case the fused bisalt conducted,
and was decomposed; but a little gas appeared at the
negative electrode; and though I believe the salt
itself was electrolyzed, I am not quite satisfied
that water was entirely absent.
700. Then a biborate of soda
was prepared; and this, I think, is an unobjectionable
case. The salt, when fused, conducted, and was
decomposed, and gas appeared at both electrodes:
even when the boracic acid was increased to three
proportionals, the same effect took place.
701. Hence this class of compound
combinations does not seem to be subject to the same
simple law as the former class of binary combinations.
Whether we may find reason to consider them as mere
solutions of the compound of single proportionals
in the excess of acid, is a matter which, with some
apparent exceptions occurring amongst the sulphurets,
must be left for decision by future examination.
702. In any investigation of
these points, great care must be taken to exclude
water; for if present, secondary effects are so frequently
produced as often seemingly to indicate an electro-decomposition
of substances, when no true result of the kind has
occurred (742, &c.).
703. It is evident that all the
cases in which decomposition does not occur, may
depend upon the want of conduction (677. 413.); but
that does not at all lessen the interest excited by
seeing the great difference of effect due to a change,
not in the nature of the elements, but merely in their
proportions; especially in any attempt which may be
made to elucidate and expound the beautiful theory
put forth by Sir Humphry Davy, and illustrated
by Berzelius and other eminent philosophers, that ordinary
chemical affinity is a mere result of the electrical
attractions of the particles of matter.
v. On a new measure of Volta-electricity.
704. I have already said, when
engaged in reducing common and voltaic electricity
to one standard of measurement (377.), and again when
introducing my theory of electro-chemical decomposition
(504. 505. 510.), that the chemical decomposing action
of a current is constant for a constant quantity
of electricity, notwithstanding the greatest variations
in its sources, in its intensity, in the size of the
electrodes used, in the nature of the conductors
(or non-conductors (307.)) through which it is passed,
or in other circumstances. The conclusive proofs
of the truth of these statements shall be given almost
immediately (783, &c.).
705. I endeavoured upon this
law to construct an instrument which should measure
out the electricity passing through it, and which,
being interposed in the course of the current used
in any particular experiment, should serve at pleasure,
either as a comparative standard of effect,
or as a positive measurer of this subtile agent.
706. There is no substance better
fitted, under ordinary circumstances, to be the indicating
body in such an instrument than water; for it is decomposed
with facility when rendered a better conductor by the
addition of acids or salts; its elements may in numerous
cases be obtained and collected without any embarrassment
from secondary action, and, being gaseous, they are
in the best physical condition for separation and
measurement. Water, therefore, acidulated by sulphuric
acid, is the substance I shall generally refer to,
although it may become expedient in peculiar cases
or forms of experiment to use other bodies (843.).
707. The first precaution needful
in the construction of the instrument was to avoid
the recombination of the evolved gases, an effect which
the positive electrode has been found so capable of
producing (571.). For this purpose various forms
of decomposing apparatus were used. The first
consisted of straight tubes, each containing a plate
and wire of platina soldered together by gold, and
fixed hermetically in the glass at the closed extremity
of the tube (Plate V. fi.). The tubes were
about eight inches long, 0.7 of an inch in diameter,
and graduated. The platina plates were about
an inch long, as wide as the tubes would permit, and
adjusted as near to the mouths of the tubes as was
consistent with the safe collection of the gases evolved.
In certain cases, where it was required to evolve
the elements upon as small a surface as possible, the
metallic extremity, instead of being a plate, consisted
of the wire bent into the form of a ring (fi.).
When these tubes were used as measurers, they were
filled with the dilute sulphuric acid, inverted in
a basin of the same liquid (fi.), and placed
in an inclined position, with their mouths near to
each other, that as little decomposing matter should
intervene as possible; and also, in such a direction
that the platina plates should be in vertical planes
(720).
708. Another form of apparatus
is that delineated (fi.). The tube is bent
in the middle; one end is closed; in that end is fixed
a wire and plate, a, proceeding so far downwards,
that, when in the position figured, it shall be as
near to the angle as possible, consistently with the
collection, at the closed extremity of the tube, of
all the gas evolved against it. The plane of
this plate is also perpendicular (720.). The other
metallic termination, b, is introduced at the
time decomposition is to be effected, being brought
as near the angle as possible, without causing any
gas to pass from it towards the closed end of the instrument.
The gas evolved against it is allowed to escape.
709. The third form of apparatus
contains both electrodes in the same tube; the transmission,
therefore, of the electricity, and the consequent
decomposition, is far more rapid than in the separate
tubes. The resulting gas is the sum of the portions
evolved at the two electrodes, and the instrument
is better adapted than either of the former as a measurer
of the quantity of voltaic electricity transmitted
in ordinary cases. It consists of a straight
tube (fi.) closed at the upper extremity, and
graduated, through the sides of which pass platina
wires (being fused into the glass), which are connected
with two plates within. The tube is fitted by
grinding into one mouth of a double-necked bottle.
If the latter be one-half or two-thirds full of the
dilute sulphuric acid (706.), it will, upon inclination
of the whole, flow into the tube and fill it.
When an electric current is passed through the instrument,
the gases evolved against the plates collect in the
upper portion of the tube, and are not subject to the
recombining power of the platina.
710. Another form of the instrument is given
at fi.
711. A fifth form is delineated
(fi.). This I have found exceedingly useful
in experiments continued in succession for days together,
and where large quantities of indicating gas were
to be collected. It is fixed on a weighted foot,
and has the form of a small retort containing the two
electrodes: the neck is narrow, and sufficiently
long to deliver gas issuing from it into a jar placed
in a small pneumatic trough. The electrode chamber,
sealed hermetically at the part held in the stand,
is five inches in length, and 0.6 of an inch in diameter;
the neck about nine inches in length, and 0.4 of an
inch in diameter internally. The figure will
fully indicate the construction.
712. It can hardly be requisite
to remark, that in the arrangement of any of these
forms of apparatus, they, and the wires connecting
them with the substance, which is collaterally subjected
to the action of the same electric current, should
be so far insulated as to ensure a certainty that
all the electricity which passes through the one shall
also be transmitted through the other.
713. Next to the precaution of
collecting the gases, if mingled, out of contact with
the platinum, was the necessity of testing the law
of a definite electrolytic action, upon water
at least, under all varieties of condition; that,
with a conviction of its certainty, might also be obtained
a knowledge of those interfering circumstances which
would require to be practically guarded against.
714. The first point investigated
was the influence or indifference of extensive variations
in the size of the electrodes, for which purpose instruments
like those last described (709. 710. 711.) were used.
One of these had plates 0.7 of an inch wide, and nearly
four inches long; another had plates only 0.5 of an
inch wide, and 0.8 of an inch long; a third had wires
0.02 of an inch in diameter, and three inches long;
and a fourth, similar wires only half an inch in length.
Yet when these were filled with dilute sulphuric acid,
and, being placed in succession, had one common current
of electricity passed through them, very nearly the
same quantity of gas was evolved in all. The
difference was sometimes in favour of one and sometimes
on the side of another; but the general result was
that the largest quantity of gases was evolved at
the smallest electrodes, namely, those consisting
merely of platina wires.
715. Experiments of a similar
kind were made with the single-plate, straight tubes
(707.), and also with the curved tubes (708.), with
similar consequences; and when these, with the former
tubes, were arranged together in various ways, the
result, as to the equality of action of large and
small metallic surfaces when delivering and receiving
the same current of electricity, was constantly the
same. As an illustration, the following numbers
are given. An instrument with two wires evolved
74.3 volumes of mixed gases; another with plates 73.25
volumes; whilst the sum of the oxygen and hydrogen
in two separate tubes amounted to 73.65 volumes.
In another experiment the volumes were 55.3, 55.3,
and 54.4.
716. But it was observed in these
experiments, that in single-plate tubes (707.) more
hydrogen was evolved at the negative electrode than
was proportionate to the oxygen at the positive electrode;
and generally, also, more than was proportionate to
the oxygen and hydrogen in a double-plate tube.
Upon more minutely examining these effects, I was led
to refer them, and also the differences between wires
and plates (714.), to the solubility of the gases
evolved, especially at the positive electrode.
717. When the positive and negative
electrodes are equal in surface, the bubbles which
rise from them in dilute sulphuric acid are always
different in character. Those from the positive
plate are exceedingly small, and separate instantly
from every part of the surface of the metal, in consequence
of its perfect cleanliness (633.); whilst in the liquid
they give it a hazy appearance, from their number
and minuteness; are easily carried down by currents,
and therefore not only present far greater surface
of contact with the liquid than larger bubbles would
do, but are retained a much longer time in mixture
with it. But the bubbles at the negative surface,
though they constitute twice the volume of the gas
at the positive electrode, are nevertheless very inferior
in number. They do not rise so universally from
every part of the surface, but seem to be evolved
at different parts; and though so much larger, they
appear to cling to the metal, separating with difficulty
from it, and when separated, instantly rising to the
top of the liquid. If, therefore, oxygen and hydrogen
had equal solubility in, or powers of combining with,
water under similar circumstances, still under the
present conditions the oxygen would be far the most
liable to solution; but when to these is added its
well-known power of forming a compound with water,
it is no longer surprising that such a compound should
be produced in small quantities at the positive electrode;
and indeed the blenching power which some philosophers
have observed in a solution at this electrode, when
chlorine and similar bodies have been carefully excluded,
is probably due to the formation there, in this manner,
of oxywater.
718. That more gas was collected
from the wires than from the plates, I attribute to
the circumstance, that as equal quantities were evolved
in equal times, the bubbles at the wires having been
more rapidly produced, in relation to any part of
the surface, must have been much larger; have been
therefore in contact with the fluid by a much smaller
surface, and for a much shorter time than those at
the plates; hence less solution and a greater amount
collected.
719. There was also another effect
produced, especially by the use of large electrodes,
which was both a consequence and a proof of the solution
of part of the gas evolved there. The collected
gas, when examined, was found to contain small portions
of nitrogen. This I attribute to the presence
of air dissolved in the acid used for decomposition.
It is a well-known fact, that when bubbles of a gas
but slightly soluble in water or solutions pass through
them, the portion of this gas which is dissolved displaces
a portion of that previously in union with the liquid:
and so, in the decompositions under consideration,
as the oxygen dissolves, it displaces a part of the
air, or at least of the nitrogen, previously united
to the acid; and this effect takes place most extensively
with large plates, because the gas evolved at them
is in the most favourable condition for solution,
720. With the intention of avoiding
this solubility of the gases as much as possible,
I arranged the decomposing plates in a vertical position
(707. 708.), that the bubbles might quickly escape
upwards, and that the downward currents in the fluid
should not meet ascending currents of gas. This
precaution I found to assist greatly in producing constant
results, and especially in experiments to be hereafter
referred to, in which other liquids than dilute sulphuric
acid, as for instance solution of potash, were used.
721. The irregularities in the
indications of the measurer proposed, arising from
the solubility just referred to, are but small, and
may be very nearly corrected by comparing the results
of two or three experiments. They may also be
almost entirely avoided by selecting that solution
which is found to favour them in the least degree
(728.); and still further by collecting the hydrogen
only, and using that as the indicating gas; for being
much less soluble than oxygen, being evolved with twice
the rapidity and in larger bubbles (717.), it can
be collected more perfectly and in greater purity.
722. From the foregoing and many
other experiments, it results that variation in
the size of the electrodes causes no variation in the
chemical action of a given quantity of electricity
upon water.
723. The next point in regard
to which the principle of constant electro-chemical
action was tested, was variation of intensity.
In the first place, the preceding experiments were
repeated, using batteries of an equal number
of plates, strongly and weakly charged;
but the results were alike. They were then repeated,
using batteries sometimes containing forty, and at
other times only five pairs of plates; but the results
were still the same. Variations therefore in the
intensity, caused by difference in the strength
of charge, or in the number of alternations used,
produced no difference as to the equal action of
large and small electrodes.
724. Still these results did
not prove that variation in the intensity of the current
was not accompanied by a corresponding variation in
the electro-chemical effects, since the actions at
all the surfaces might have increased or diminished
together. The deficiency in the evidence is,
however, completely supplied by the former experiments
on different-sized electrodes; for with variation
in the size of these, a variation in the intensity
must have occurred. The intensity of an electric
current traversing conductors alike in their nature,
quality, and length, is probably as the quantity of
electricity passing through a given sectional area
perpendicular to the current, divided by the time (360.
note); and therefore when large plates were
contrasted with wires separated by an equal length
of the same decomposing conductor (714.), whilst one
current of electricity passed through both arrangements,
that electricity must have been in a very different
state, as to tension, between the plates and
between the wires; yet the chemical results were the
same.
725. The difference in intensity,
under the circumstances described, may be easily shown
practically, by arranging two decomposing apparatus
as in fi, where the same fluid is subjected to
the decomposing power of the same current of electricity,
passing in the vessel A. between large platina plates,
and in the vessel B. between small wires. If a
third decomposing apparatus, such as that delineated
fi. (711.), be connected with the wires at ab,
fi, it will serve sufficiently well, by the degree
of decomposition occurring in it, to indicate the
relative state of the two plates as to intensity;
and if it then be applied in the same way, as a test
of the state of the wires at a’b’,
it will, by the increase of decomposition within,
show how much greater the intensity is there than at
the former points. The connexions of P and N with
the voltaic battery are of course to be continued
during the whole time.
726. A third form of experiment,
in which difference of intensity was obtained, for
the purpose of testing the principle of equal chemical
action, was to arrange three volta-electrometers,
so that after the electric current had passed through
one, it should divide into two parts, each of which
should traverse one of the remaining instruments, and
should then reunite. The sum of the decomposition
in the two latter vessels was always equal to the
decomposition in the former vessel. But the intensity
of the divided current could not be the same as that
it had in its original state; and therefore variation
of intensity has no influence on the results if the
quantity of electricity remain the same. The
experiment, in fact, resolves itself simply into an
increase in the size of the electrodes (725.).
727. The third point,
in respect to which the principle of equal electro-chemical
action on water was tested, was variation of the
strength of the solution used. In order to
render the water a conductor, sulphuric acid had been
added to it (707.); and it did not seem unlikely that
this substance, with many others, might render the
water more subject to decomposition, the electricity
remaining the same in quantity. But such did
not prove to be the case. Diluted sulphuric acid,
of different strengths, was introduced into different
decomposing apparatus, and submitted simultaneously
to the action of the same electric current (714.).
Slight differences occurred, as before, sometimes
in one direction, sometimes in another; but the final
result was, that exactly the same quantity of water
was decomposed in all the solutions by the same quantity
of electricity, though the sulphuric acid in some
was seventy-fold what it was in others. The strengths
used were of specific gravity 1.495, and downwards.
728. When an acid having a specific
gravity of about 1.336 was employed, the results were
most uniform, and the oxygen and hydrogen (716.) most
constantly in the right proportion to each other.
Such an acid gave more gas than one much weaker acted
upon by the same current, apparently because it had
less solvent power. If the acid were very strong,
then a remarkable disappearance of oxygen took place;
thus, one made by mixing two measures of strong oil
of vitriol with one of water, gave forty-two volumes
of hydrogen, but only twelve of oxygen. The hydrogen
was very nearly the same with that evolved from acid
of the specific gravity 1.232. I have not yet
had time to examine minutely the circumstances attending
the disappearance of the oxygen in this case, but
imagine it is due to the formation of oxywater, which
Thenard has shown is favoured by the presence of acid.
729. Although not necessary for
the practical use of the instrument I am describing,
yet as connected with the important point of constant
chemical action upon water, I now investigated the
effects produced by an electro-electric current passing
through aqueous solutions of acids, salts, and compounds,
exceedingly different from each other in their nature,
and found them to yield astonishingly uniform results.
But many of them which are connected with a secondary
action will be more usefully described hereafter (778.).
730. When solutions of caustic
potassa or soda, or sulphate of magnesia, or sulphate
of soda, were acted upon by the electric current, just
as much oxygen and hydrogen was evolved from them
as from the diluted sulphuric acid, with which they
were compared. When a solution of ammonia, rendered
a better conductor by sulphate of ammonia (554.),
or a solution of subcarbonate of potassa was experimented
with, the hydrogen evolved was in the same
quantity as that set free from the diluted sulphuric
acid with which they were compared. Hence changes
in the nature of the solution do not alter the constancy
of electrolytic action upon water.
731. I have already said, respecting
large and small electrodes, that change of order caused
no change in the general effect (715.). The same
was the case with different solutions, or with different
intensities; and however the circumstances of an experiment
might be varied, the results came forth exceedingly
consistent, and proved that the electro-chemical action
was still the same.
732. I consider the foregoing
investigation as sufficient to prove the very extraordinary
and important principle with respect to WATER, that
when subjected to the influence of the electric current,
a quantity of it is decomposed exactly proportionate
to the quantity of electricity which has passed,
notwithstanding the thousand variations in the conditions
and circumstances under which it may at the time be
placed; and further, that when the interference of
certain secondary effects (742. &c.), together with
the solution or recombination of the gas and the evolution
of air, are guarded against, the products of the
decomposition may be collected with such accuracy,
as to afford a very excellent and valuable measurer
of the electricity concerned in their evolution.
733. The forms of instrument
which I have given, fig, 65, 66. (709. 710. 711.),
are probably those which will be found most useful,
as they indicate the quantity of electricity by the
largest volume of gases, and cause the least obstruction
to the passage of the current. The fluid which
my present experience leads me to prefer, is a solution
of sulphuric acid of specific gravity about 1.336,
or from that to 1.25; but it is very essential that
there should be no organic substance, nor any vegetable
acid, nor other body, which, by being liable to the
action of the oxygen or hydrogen evolved at the electrodes
(773. &c.), shall diminish their quantity, or add
other gases to them.
734. In many cases when the instrument
is used as a comparative standard, or even
as a measurer, it may be desirable to collect
the hydrogen only, as being less liable to absorption
or disappearance in other ways than the oxygen; whilst
at the same time its volume is so large, as to render
it a good and sensible indicator. In such cases
the first and second form of apparatus have been used,
fig, 63. (707. 708.). The indications obtained
were very constant, the variations being much smaller
than in those forms of apparatus collecting both gases;
and they can also be procured when solutions are used
in comparative experiments, which, yielding no oxygen
or only secondary results of its action, can give no
indications if the educts at both electrodes be collected.
Such is the case when solutions of ammonia, muriatic
acid, chlorides, iodides, acétates or other vegetable
salts, &c., are employed.
735. In a few cases, as where
solutions of metallic salts liable to reduction at
the negative electrode are acted upon, the oxygen may
be advantageously used as the measuring substance.
This is the case, for instance, with sulphate of copper.
736. There are therefore two
general forms of the instrument which I submit as
a measurer of electricity; one, in which both the gases
of the water decomposed are collected (709. 710. 711.);
and the other, in which a single gas, as the hydrogen
only, is used (707. 708.). When referred to as
a comparative instrument, (a use I shall now
make of it very extensively,) it will not often require
particular precaution in the observation; but when
used as an absolute measurer, it will be needful
that the barometric pressure and the temperature be
taken into account, and that the graduation of the
instruments should be to one scale; the hundredths
and smaller divisions of a cubical inch are quite
fit for this purpose, and the hundredth may be very
conveniently taken as indicating a DEGREE of electricity.
737. It can scarcely be needful
to point out further than has been done how this instrument
is to be used. It is to be introduced into the
course of the electric current, the action of which
is to be exerted anywhere else, and if 60 deg.
or 70 deg. of electricity are to be measured out,
either in one or several portions, the current, whether
strong or weak, is to be continued until the gas in
the tube occupies that number of divisions or hundredths
of a cubical inch. Or if a quantity competent
to produce a certain effect is to be measured, the
effect is to be obtained, and then the indication
read off. In exact experiments it is necessary
to correct the volume of gas for changes in temperature
and pressure, and especially for moisture.
For the latter object the volta-electrometer (fi.) is most accurate, as its gas can be measured
over water, whilst the others retain it over acid
or saline solutions.
738. I have not hesitated to
apply the term degree (736.), in analogy with
the use made of it with respect to another most important
imponderable agent, namely, heat; and as the definite
expansion of air, water, mercury, &c., is there made
use of to measure heat, so the equally definite evolution
of gases is here turned to a similar use for electricity.
739. The instrument offers the
only actual measurer of voltaic electricity
which we at present possess. For without being
at all affected by variations in time or intensity,
or alterations in the current itself, of any kind,
or from any cause, or even of intermissions of action,
it takes note with accuracy of the quantity of electricity
which has passed through it, and reveals that quantity
by inspection; I have therefore named it a VOLTA-ELECTROMETER.
740. Another mode of measuring
volta-electricity may be adopted with advantage
in many cases, dependent on the quantities of metals
or other substances evolved either as primary or as
secondary results; but I refrain from enlarging on
this use of the products, until the principles on which
their constancy depends have been fully established
(791. 848.);
741. By the aid of this instrument
I have been able to establish the definite character
of electro-chemical action in its most general sense;
and I am persuaded it will become of the utmost use
in the extensions of the science which these views
afford. I do not pretend to have made its detail
perfect, but to have demonstrated the truth of the
principle, and the utility of the application.
vi. On the primary or secondary
character of the bodies evolved at the Electrodes.
742. Before the volta-electrometer
could be employed in determining, as a general
law, the constancy of electro-decomposition, it
became necessary to examine a distinction, already
recognised among scientific men, relative to the products
of that action, namely, their primary or secondary
character; and, if possible, by some general rule or
principle, to decide when they were of the one or
the other kind. It will appear hereafter that
great mistakes inspecting electro-chemical action and
its consequences have arisen from confounding these
two classes of results together.
743. When a substance under decomposition
yields at the electrodes those bodies uncombined and
unaltered which the electric current has separated,
then they may be considered as primary results, even
though themselves compounds. Thus the oxygen
and hydrogen from water are primary results; and so
also are the acid and alkali (themselves compound bodies)
evolved from sulphate of soda. But when the substances
separated by the current are changed at the electrodes
before their appearance, then they give rise to secondary
results, although in many cases the bodies evolved
are elementary.
744. These secondary results
occur in two ways, being sometimes due to the mutual
action of the evolved substance and the matter of the
electrode, and sometimes to its action upon the substances
contained in the body itself under decomposition.
Thus, when carbon is made the positive electrode in
dilute sulphuric acid, carbonic oxide and carbonic
acid occasionally appear there instead of oxygen;
for the latter, acting upon the matter of the electrode,
produces these secondary results. Or if the positive
electrode, in a solution of nitrate or acetate of
lead, be platina, then peroxide of lead appears there,
equally a secondary result with the former, but now
depending upon an action of the oxygen on a substance
in the solution. Again, when ammonia is decomposed
by platina electrodes, nitrogen appears at the anode;
but though an elementary body, it is a secondary
result in this case, being derived from the chemical
action of the oxygen electrically evolved there, upon
the ammonia in the surrounding solution (554.).
In the same manner when aqueous solutions of metallic
salts are decomposed by the current, the metals evolved
at the cathode, though elements, are always
secondary results, and not immediate consequences of
the decomposing power of the electric current.
745. Many of these secondary
results are extremely valuable; for instance, all
the interesting compounds which M. Becquerel has obtained
by feeble electric currents are of this nature; but
they are essentially chemical, and must, in the theory
of electrolytic action, be carefully distinguished
from those which are directly due to the action of
the electric current.
746. The nature of the substances
evolved will often lead to a correct judgement of
their primary or secondary character, but is not sufficient
alone to establish that point. Thus, nitrogen
is said to be attracted sometimes by the positive
and sometimes by the negative electrode, according
to the bodies with which it may be combined (554. 555.),
and it is on such occasions evidently viewed as a
primary result; but I think I shall show, that,
when it appears at the positive electrode, or rather
at the anode, it is a secondary result (748.).
Thus, also, Sir Humphry Davy, and with him the
great body of chemical philosophers, (including myself,)
have given the appearance of copper, lead, tin, silver,
gold, &c., at the negative electrode, when their aqueous
solutions were acted upon by the voltaic current,
as proofs that the metals, as a class, were attracted
to that surface; thus assuming the metal, in each case,
to be a primary result. These, however, I expect
to prove, are all secondary results; the mere consequence
of chemical action, and no proofs either of the attraction
or of the law announced respecting their places.
747. But when we take to our
assistance the law of constant electro-chemical
action already proved with regard to water (732.),
and which I hope to extend satisfactorily to all bodies
(821.), and consider the quantities as well
as the nature of the substances set free, a
generally accurate judgement of the primary or secondary
character of the results may be formed: and this
important point, so essential to the theory of electrolyzation,
since it decides what are the particles directly under
the influence of the current, (distinguishing them
from such as are not affected,) and what are the results
to be expected, may be established with such degree
of certainty as to remove innumerable ambiguities and
doubtful considerations from this branch of the science.
748. Let us apply these principles
to the case of ammonia, and the supposed determination
of nitrogen to one or the other electrode (554.
555,). A pure strong solution of ammonia is as
bad a conductor, and therefore as little liable to
electrolyzation, as pure water; but when sulphate of
ammonia is dissolved in it, the whole becomes a conductor;
nitrogen almost and occasionally quite
pure is evolved at the anode, and hydrogen
at the cathode; the ratio of the volume of the
former to that of the latter varying, but being as
1 to about 3 or 4. This result would seem at
first to imply that the electric current had decomposed
ammonia, and that the nitrogen had been determined
towards the positive electrode. But when the
electricity used was measured out by the volta-electrometer
(707. 736.), it was found that the hydrogen obtained
was exactly in the proportion which would have been
supplied by decomposed water, whilst the nitrogen
had no certain or constant relation whatever.
When, upon multiplying experiments, it was found that,
by using a stronger or weaker solution, or a more
or less powerful battery, the gas evolved at the anode
was a mixture of oxygen and nitrogen, varying both
in proportion and absolute quantity, whilst the hydrogen
at the cathode remained constant, no doubt
could be entertained that the nitrogen at the anode
was a secondary result, depending upon the chemical
action of the nascent oxygen, determined to that surface
by the electric current, upon the ammonia in solution.
It was the water, therefore, which was electrolyzed,
not the ammonia. Further, the experiment gives
no real indication of the tendency of the element
nitrogen to either one electrode or the other; nor
do I know of any experiment with nitric acid, or other
compounds of nitrogen, which shows the tendency of
this element, under the influence of the electric
current, to pass in either direction along its course.
749. As another illustration
of secondary results, the effects on a solution of
acetate of potassa, may be quoted. When a very
strong solution was used, more gas was evolved at
the anode than at the cathode, in the
proportion of 4 to 3 nearly: that from the anode
was a mixture of carbonic oxide and carbonic acid;
that from the cathode pure hydrogen. When
a much weaker solution was used, less gas was evolved
at the anode than at the cathode; and
it now contained carburetted hydrogen, as well as
carbonic oxide and carbonic acid. This result
of carburetted hydrogen at the positive electrode
has a very anomalous appearance, if considered as an
immediate consequence of the decomposing power of the
current. It, however, as well as the carbonic
oxide and acid, is only a secondary result;
for it is the water alone which suffers electro-decomposition,
and it is the oxygen eliminated at the anode
which, reacting on the acetic acid, in the midst of
which it is evolved, produces those substances that
finally appear there. This is fully proved by
experiments with the volta-electrometer (707.);
for then the hydrogen evolved from the acetate at the
cathode is always found to be definite, being
exactly proportionate to the electricity which has
passed through the solution, and, in quantity, the
same as the hydrogen evolved in the volta-electrometer
itself. The appearance of the carbon in combination
with the hydrogen at the positive electrode, and its
non-appearance at the negative electrode, are in curious
contrast with the results which might have been expected
from the law usually accepted respecting the final
places of the elements.
750. If the salt in solution
be an acetate of lead, then the results at both electrodes
are secondary, and cannot be used to estimate or express
the amount of electro-chemical action, except by a
circuitous process (843.). In place of oxygen
or even the gases already described (749.), peroxide
of lead now appears at the positive, and lead itself
at the negative electrode. When other metallic
solutions are used, containing, for instance, peroxides,
as that of copper, combined with this or any other
decomposable acid, still more complicated results will
be obtained; which, viewed as direct results of the
electro-chemical action, will, in their proportions,
present nothing but confusion, but will appear perfectly
harmonious and simple if they be considered as secondary
results, and will accord in their proportions with
the oxygen and hydrogen evolved from water by the
action of a definite quantity of electricity.
751. I have experimented upon
many bodies, with a view to determine whether the
results were primary or secondary. I have been
surprised to find how many of them, in ordinary cases,
are of the latter class, and how frequently water
is the only body electrolyzed in instances where other
substances have been supposed to give way. Some
of these results I will give in as few words as possible.
752. Nitric acid.—When
very strong, it conducted well, and yielded oxygen
at the positive electrode. No gas appeared at
the negative electrode; but nitrous acid, and apparently
nitric oxide, were formed there, which, dissolving,
rendered the acid yellow or red, and at last even
effervescent, from the spontaneous separation of nitric
oxide. Upon diluting the acid with its bulk or
more of water, gas appeared at the negative electrode.
Its quantity could be varied by variations, either
in the strength of the acid or of the voltaic current:
for that acid from which no gas separated at the cathode,
with a weak voltaic battery, did evolve gas there
with a stronger; and that battery which evolved no
gas there with a strong acid, did cause its evolution
with an acid more dilute. The gas at the anode
was always oxygen; that at the cathode hydrogen.
When the quantity of products was examined by the volta-electrometer
(707.), the oxygen, whether from strong or weak acid,
proved to be in the same proportion as from water.
When the acid was diluted to specific gravity 1.24,
or less, the hydrogen also proved to be the same in
quantity as from water. Hence I conclude that
the nitric acid does not undergo electrolyzation,
but the water only; that the oxygen at the anode
is always a primary result, but that the products
at the cathode are often secondary, and due
to the reaction of the hydrogen upon the nitric acid.
753. Nitre.—A solution
of this salt yields very variable results, according
as one or other form of tube is used, or as the electrodes
are large or small. Sometimes the whole of the
hydrogen of the water decomposed may be obtained at
the negative electrode; at other times, only a part
of it, because of the ready formation of secondary
results. The solution is a very excellent conductor
of electricity.
754. Nitrate of ammonia, in
aqueous solution, gives rise to secondary results
very varied and uncertain in their proportions.
755. Sulphurous acid.—Pure
liquid sulphurous acid does not conduct nor suffer
decomposition by the voltaic current, but, when
dissolved in water, the solution acquires conducting
power, and is decomposed, yielding oxygen at the anode,
and hydrogen and sulphur at the cathode.
756. A solution containing sulphuric
acid in addition to the sulphurous acid, was a better
conductor. It gave very little gas at either electrode:
that at the anode was oxygen, that at the cathode
pure hydrogen. From the cathode also rose
a white turbid stream, consisting of diffused sulphur,
which soon rendered the whole solution milky.
The volumes of gases were in no regular proportion
to the quantities evolved from water in the voltameter.
I conclude that the sulphurous acid was not at all
affected by the electric current in any of these cases,
and that the water present was the only body electro-chemically
decomposed; that, at the anode, the oxygen
from the water converted the sulphurous acid into sulphuric
acid, and, at the cathode, the hydrogen electrically
evolved decomposed the sulphurous acid, combining
with its oxygen, and setting its sulphur free.
I conclude that the sulphur at the negative electrode
was only a secondary result; and, in fact, no part
of it was found combined with the small portion of
hydrogen which escaped when weak solutions of sulphurous
acid were used.
757. Sulphuric acid.—I
have already given my reasons for concluding that
sulphuric acid is not electrolyzable, i.e. not
decomposable directly by the electric current, but
occasionally suffering by a secondary action at the
cathode from the hydrogen evolved there (681.).
In the year 1800, Davy considered the sulphur from
sulphuric acid as the result of the action of the
nascent hydrogen. In 1804, Hisinger and Berzelius
stated that it was the direct result of the action
of the voltaic pile, an opinion which from that
time Davy seems to have adopted, and which has since
been commonly received by all. The change of
my own opinion requires that I should correct what
I have already said of the decomposition of sulphuric
acid in a former series of these Researches (552.):
I do not now think that the appearance of the sulphur
at the negative electrode is an immediate consequence
of electrolytic action.
758. Muriatic acid.—A
strong solution gave hydrogen at the negative electrode,
and chlorine only at the positive electrode; of the
latter, a part acted on the platina and a part was
dissolved. A minute bubble of gas remained; it
was not oxygen, but probably air previously held in
solution.
759. It was an important matter
to determine whether the chlorine was a primary result,
or only a secondary product, due to the action of the
oxygen evolved from water at the anode upon
the muriatic acid; i.e. whether the muriatic
acid was electrolyzable, and if so, whether the decomposition
was definite.
760. The muriatic acid was gradually
diluted. One part with six of water gave only
chlorine at the anode. One part with eight
of water gave only chlorine; with nine of water, a
little oxygen appeared with the chlorine; but the
occurrence or non-occurrence of oxygen at these strengths
depended, in part, on the strength of the voltaic
battery used. With fifteen parts of water, a
little oxygen, with much chlorine, was evolved at the
anode. As the solution was now becoming
a bad conductor of electricity, sulphuric acid was
added to it: this caused more ready decomposition,
but did not sensibly alter the proportion of chlorine
and oxygen.
761. The muriatic acid was now
diluted with 100 times its volume of dilute sulphuric
acid. It still gave a large proportion of chlorine
at the anode, mingled with oxygen; and the
result was the same, whether a voltaic battery of
40 pairs of plates or one containing only 5 pairs were
used. With acid of this strength, the oxygen evolved
at the anode was to the hydrogen at the cathode,
in volume, as 17 is to 64; and therefore the chlorine
would have been 30 volumes, had it not been dissolved
by the fluid.
762. Next with respect to the
quantity of elements evolved. On using the volta-electrometer,
it was found that, whether the strongest or the weakest
muriatic acid were used, whether chlorine alone or
chlorine mingled with oxygen appeared at the anode,
still the hydrogen evolved at the cathode was
a constant quantity, i.e. exactly the same as
the hydrogen which the same quantity of electricity
could evolve from water.
763. This constancy does not
decide whether the muriatic acid is electrolyzed or
not, although it proves that if so, it must be in definite
proportions to the quantity of electricity used.
Other considerations may, however, be allowed to decide
the point. The analogy between chlorine and oxygen,
in their relations to hydrogen, is so strong, as to
lead almost to the certainty, that, when combined
with that element, they would perform similar parts
in the process of electro-decomposition. They
both unite with it in single proportional or equivalent
quantities; and the number of proportionals appearing
to have an intimate and important relation to the
decomposability of a body (697.), those in muriatic
acid, as well as in water, are the most favourable,
or those perhaps even necessary, to decomposition.
In other binary compounds of chlorine also, where nothing
equivocal depending on the simultaneous presence of
it and oxygen is involved, the chlorine is directly
eliminated at the anode by the electric current.
Such is the case with the chloride of lead (395.),
which may be justly compared with protoxide of lead
(402.), and stands in the same relation to it as muriatic
acid to water. The chlorides of potassium, sodium,
barium, &c., are in the same relation to the protoxides
of the same metals and present the same results under
the influence of the electric current (402.).
764. From all the experiments,
combined with these considerations, I conclude that
muriatic acid is decomposed by the direct influence
of the electric current, and that the quantities evolved
are, and therefore the chemical action is, definite
for a definite quantity of electricity. For
though I have not collected and measured the chlorine,
in its separate state, at the anode, there
can exist no doubt as to its being proportional to
the hydrogen at the cathode; and the results
are therefore sufficient to establish the general
law of constant electro-chemical action in
the case of muriatic acid.
765. In the dilute acid (761.),
I conclude that a part of the water is electro-chemically
decomposed, giving origin to the oxygen, which appears
mingled with the chlorine at the anode.
The oxygen may be viewed as a secondary result;
but I incline to believe that it is not so; for, if
it were, it might be expected in largest proportion
from the stronger acid, whereas the reverse is the
fact. This consideration, with others, also leads
me to conclude that muriatic acid is more easily decomposed
by the electric current than water; since, even when
diluted with eight or nine times its quantity of the
latter fluid, it alone gives way, the water remaining
unaffected.
766. Chlorides.—On
using solutions of chlorides in water,—for
instance, the chlorides of sodium or calcium,—there
was evolution of chlorine only at the positive electrode,
and of hydrogen, with the oxide of the base, as soda
or lime, at the negative electrode. The process
of decomposition may be viewed as proceeding in two
or three ways, all terminating in the same results.
Perhaps the simplest is to consider the chloride as
the substance electrolyzed, its chlorine being determined
to and evolved at the anode, and its metal
passing to the cathode, where, finding no more
chlorine, it acts upon the water, producing hydrogen
and an oxide as secondary results. As the discussion
would detain me from more important matter, and is
not of immediate consequence, I shall defer it for
the present. It is, however, of great consequence
to state, that, on using the volta-electrometer,
the hydrogen in both cases was definite; and if the
results do not prove the definite decomposition of
chlorides, (which shall be proved elsewhere,—789.
794. 814.,) they are not in the slightest degree opposed
to such a conclusion, and do support the general
law.
767. Hydriodic acid.—A
solution of hydriodic acid was affected exactly in
the same manner as muriatic acid. When strong,
hydrogen was evolved at the negative electrode, in
definite proportion to the quantity of electricity
which had passed, i.e. in the same proportion
as was evolved by the same current from water; and
iodine without any oxygen was evolved at the positive
electrode. But when diluted, small quantities
of oxygen appeared with the iodine at the anode,
the proportion of hydrogen at the cathode remaining
undisturbed.
768. I believe the decomposition
of the hydriodic acid in this case to be direct, for
the reasons already given respecting muriatic acid
(763. 764.).
769. Iodides.—A
solution of iodide of potassium being subjected to
the voltaic current, iodine appeared at the positive
electrode (without any oxygen), and hydrogen with
free alkali at the negative electrode. The same
observations as to the mode of decomposition are applicable
here as were made in relation to the chlorides when
in solution (766.).
770. Hydro-fluoric acid and fluorides.—Solution
of hydrofluoric acid did not appear to be decomposed
under the influence of the electric current: it
was the water which gave way apparently. The fused
fluorides were electrolysed (417.); but having during
these actions obtained fluorine in the separate
state, I think it better to refer to a future series
of these Researches, in which I purpose giving a fuller
account of the results than would be consistent with
propriety here.
771. Hydro-cyanic acid in solution
conducts very badly. The definite proportion
of hydrogen (equal to that from water) was set free
at the cathode, whilst at the anode
a small quantity of oxygen was evolved and apparently
a solution of cyanogen formed. The action altogether
corresponded with that on a dilute muriatic or hydriodic
acid. When the hydrocyanic acid was made a better
conductor by sulphuric acid, the same results occurred.
Cyanides.—With a
solution of the cyanide of potassium, the result was
precisely the same as with a chloride or iodide.
No oxygen was evolved at the positive electrode, but
a brown solution formed there. For the reasons
given when speaking of the chlorides (766.), and because
a fused cyanide of potassium evolves cyanogen at the
positive electrode, I incline to believe that the
cyanide in solution is directly decomposed.
772. Ferro-cyanic acid and
the ferro-cyanides, as also sulpho-cyanic
acid and the sulpho-cyanides, presented
results corresponding with those just described (771.).
773. Acetic acid.—Glacial
acetic acid, when fused (405.), is not decomposed
by, nor does it conduct, electricity. On adding
a little water to it, still there were no signs of
action; on adding more water, it acted slowly and
about as pure water would do. Dilute sulphuric
acid was added to it in order to make it a better
conductor; then the definite proportion of hydrogen
was evolved at the cathode, and a mixture of
oxygen in very deficient quantity, with carbonic acid,
and a little carbonic oxide, at the anode.
Hence it appears that acetic acid is not electrolyzable,
but that a portion of it is decomposed by the oxygen
evolved at the anode, producing secondary results,
varying with the strength of the acid, the intensity
of the current, and other circumstances.
774. Acétates.—One
of these has been referred to already, as affording
only secondary results relative to the acetic acid
(749.). With many of the metallic acétates
the results at both electrodes are secondary (746.
750.).
Acetate of soda fused and anhydrous
is directly decomposed, being, as I believe, a true
electrolyte, and evolving soda and acetic acid at the
cathode and anode. These however
have no sensible duration, but are immediately resolved
into other substances; charcoal, sodiuretted hydrogen,
&c., being set free at the former, and, as far as I
could judge under the circumstances, acetic acid mingled
with carbonic oxide, carbonic acid, &c. at the latter.
775. Tartaric acid.—Pure
solution of tartaric acid is almost as bad a conductor
as pure water. On adding sulphuric acid, it conducted
well, the results at the positive electrode being
primary or secondary in different proportions, according
to variations in the strength of the acid and the
power of the electric current (752.). Alkaline
tartrates gave a large proportion of secondary results
at the positive electrode. The hydrogen at the
negative electrode remained constant unless certain
triple metallic salts were used.
776. Solutions, of salts containing
other vegetable acids, as the benzoates; of sugar,
gum, &c., dissolved in dilute sulphuric acid; of resin,
albumen, &c., dissolved in alkalies, were in turn submitted
to the electrolytic power of the voltaic current.
In all these cases, secondary results to a greater
or smaller extent were produced at the positive electrode.
777. In concluding this division
of these Researches, it cannot but occur to the mind
that the final result of the action of the electric
current upon substances, placed between the electrodes,
instead of being simple may be very complicated.
There are two modes by which these substances may be
decomposed, either by the direct force of the electric
current, or by the action of bodies which that current
may evolve. There are also two modes by which
new compounds may be formed, i.e. by combination
of the evolving substances whilst in their nascent
state (658.), directly with the matter of the electrode;
or else their combination with those bodies, which
being contained in, or associated with, the body suffering
decomposition, are necessarily present at the anode
and cathode. The complexity is rendered
still greater by the circumstance that two or more
of these actions may occur simultaneously, and also
in variable proportions to each other. But it
may in a great measure be resolved by attention to
the principles already laid down (747.).
778. When aqueous solutions
of bodies are used, secondary results are exceedingly
frequent. Even when the water is not present in
large quantity, but is merely that of combination,
still secondary results often ensue: for instance,
it is very possible that in Sir Humphry Davy’s
decomposition of the hydrates of potassa and soda,
a part of the potassium produced was the result of
a secondary action. Hence, also, a frequent cause
for the disappearance of the oxygen and hydrogen which
would otherwise be evolved: and when hydrogen
does not appear at the cathode in an
aqueous solution, it perhaps always indicates
that a secondary action has taken place there.
No exception to this rule has as yet occurred to my
observation.
779. Secondary actions are not
confined to aqueous solutions, or cases where
water is present. For instance, various chlorides
acted upon, when fused (402.), by platina electrodes,
have the chlorine determined electrically to the anode.
In many cases, as with the chlorides of lead, potassium,
barium, &c., the chlorine acts on the platina and forms
a compound with it, which dissolves; but when protochloride
of tin is used, the chlorine at the anode does
not act upon the platina, but upon the chloride already
there, forming a perchloride which rises in vapour
(790. 804.). These are, therefore, instances
of secondary actions of both kinds, produced in bodies
containing no water.
780. The production of boron
from fused borax (402. 417.) is also a case of secondary
action; for boracic acid is not decomposable by electricity
(408.), and it was the sodium evolved at the cathode
which, re-acting on the boracic acid around it, took
oxygen from it and set boron free in the experiments
formerly described.
781. Secondary actions have already,
in the hands of M. Becquerel, produced many interesting
results in the formation of compounds; some of them
new, others imitations of those occurring naturally.
It is probable they may prove equally interesting
in an opposite direction, i.e. as affording cases
of analytic decomposition. Much information regarding
the composition, and perhaps even the arrangement,
of the particles of such bodies as the vegetable acids
and alkalies, and organic compounds generally, will
probably be obtained by submitting them to the action
of nascent oxygen, hydrogen, chlorine, &c. at the
electrodes; and the action seems the more promising,
because of the thorough command which we possess over
attendant circumstances, such as the strength of the
current, the size of the electrodes, the nature of
the decomposing conductor, its strength, &c., all
of which may be expected to have their corresponding
influence upon the final result.
782. It is to me a great satisfaction
that the extreme variety of secondary results has
presented nothing opposed to the doctrine of a constant
and definite electro-chemical action, to the particular
consideration of which I shall now proceed.
vii. On the definite nature and
extent of Electro-chemical Decomposition.
783. In the third series of these
Researches, after proving the identity of electricities
derived from different sources, and showing, by actual
measurement, the extraordinary quantity of electricity
evolved by a very feeble voltaic arrangement (371.
376.), I announced a law, derived from experiment,
which seemed to me of the utmost importance to the
science of electricity in general, and that branch
of it denominated electro-chemistry in particular.
The law was expressed thus: The chemical power
of a current of electricity is in direct proportion
to the absolute quantity of electricity which passes
(377.).
784. In the further progress
of the successive investigations, I have had frequent
occasion to refer to the same law, sometimes in circumstances
offering powerful corroboration of its truth (456.
504. 505.); and the present series already supplies
numerous new cases in which it holds good (704. 722.
726. 732.). It is now my object to consider this
great principle more closely, and to develope some
of the consequences to which it leads. That the
evidence for it may be the more distinct and applicable,
I shall quote cases of decomposition subject to as
few interferences from secondary results as possible,
effected upon bodies very simple, yet very definite
in their nature.
785. In the first place, I consider
the law as so fully established with respect to the
decomposition of water, and under so many circumstances
which might be supposed, if anything could, to exert
an influence over it, that I may be excused entering
into further detail respecting that substance, or
even summing up the results here (732.). I refer,
therefore, to the whole of the subdivision of this
series of Researches which contains the account of
the volta-electrometer (704. &c.).
786. In the next place, I also
consider the law as established with respect to muriatic
acid by the experiments and reasoning already advanced,
when speaking of that substance, in the subdivision
respecting primary and secondary results (758. &c.).
787. I consider the law as established
also with regard to hydriodic acid by the experiments
and considerations already advanced in the preceding
division of this series of Researches (767. 768.).
788. Without speaking with the
same confidence, yet from the experiments described,
and many others not described, relating to hydro-fluoric,
hydro-cyanic, ferro-cyanic, and sulpho-cyanic acids
(770. 771. 772.), and from the close analogy which
holds between these bodies and the hydracids of chlorine,
iodine, bromine, &c., I consider these also as coming
under subjection to the law, and assisting to prove
its truth.
789. In the preceding cases,
except the first, the water is believed to be inactive;
but to avoid any ambiguity arising from its presence,
I sought for substances from which it should be absent
altogether; and, taking advantage of the law of conduction
already developed (380. &c.), I soon found abundance,
amongst which protochloride of tin was first
subjected to decomposition in the following manner.
A piece of platina wire had one extremity coiled up
into a small knob, and, having been carefully weighed,
was sealed hermetically into a piece of bottle-glass
tube, so that the knob should be at the bottom of
the tube within (fi.). The tube was suspended
by a piece of platina wire, so that the heat of a spirit-lamp
could be applied to it. Recently fused protochloride
of tin was introduced in sufficient quantity to occupy,
when melted, about one-half of the tube; the wire
of the tube was connected with a volta-electrometer
(711.), which was itself connected with the negative
end of a voltaic battery; and a platina wire connected
with the positive end of the same battery was dipped
into the fused chloride in the tube; being however
so bent, that it could not by any shake of the hand
or apparatus touch the negative electrode at the bottom
of the vessel. The whole arrangement is delineated
in fi.
790. Under these circumstances
the chloride of tin was decomposed: the chlorine
evolved at the positive electrode formed bichloride
of tin (779.), which passed away in fumes, and the
tin evolved at the negative electrode combined with
the platina, forming an alloy, fusible at the temperature
to which the tube was subjected, and therefore never
occasioning metallic communication through the decomposing
chloride. When the experiment had been continued
so long as to yield a reasonable quantity of gas in
the volta-electrometer, the battery connexion
was broken, the positive electrode removed, and the
tube and remaining chloride allowed to cool.
When cold, the tube was broken open, the rest of the
chloride and the glass being easily separable from
the platina wire and its button of alloy. The
latter when washed was then reweighed, and the increase
gave the weight of the tin reduced.
791. I will give the particular
results of one experiment, in illustration of the
mode adopted in this and others, the results of which
I shall have occasion to quote. The negative
electrode weighed at first 20 grains; after the experiment,
it, with its button of alloy, weighed 23.2 grains.
The tin evolved by the electric current at the cathode:
weighed therefore 3.2 grains. The quantity of
oxygen and hydrogen collected in the volta-electrometer
= 3.85 cubic inches. As 100 cubic inches of oxygen
and hydrogen, in the proportions to form water, may
be considered as weighing 12.92 grains, the 3.85 cubic
inches would weigh 0.49742 of a grain; that being,
therefore, the weight of water decomposed by the same
electric current as was able to decompose such weight
of protochloride of tin as could yield 3.2 grains
of metal. Now 0.49742 : 3.2 :: 9 the
equivalent of water is to 57.9, which should therefore
be the equivalent of tin, if the experiment had been
made without error, and if the electro-chemical decomposition
is in this case also definite. In some
chemical works 58 is given as the chemical equivalent
of tin, in others 57.9. Both are so near to the
result of the experiment, and the experiment itself
is so subject to slight causes of variation (as from
the absorption of gas in the volta-electrometer
(716.), &c.), that the numbers leave little doubt of
the applicability of the law of definite action
in this and all similar cases of electro-decomposition.
792. It is not often I have obtained
an accordance in numbers so near as that I have just
quoted. Four experiments were made on the protochloride
of tin, the quantities of gas evolved in the volta-electrometer
being from 2.05 to 10.29 cubic inches. The average
of the four experiments gave 58.53 as the electro-chemical
equivalent for tin.
793. The chloride remaining after
the experiment was pure protochloride of tin; and
no one can doubt for a moment that the equivalent of
chlorine had been evolved at the anode, and,
having formed bichloride of tin as a secondary result,
had passed away.
794. Chloride of lead was experimented
upon in a manner exactly similar, except that a change
was made in the nature of the positive electrode; for
as the chlorine evolved at the anode forms no
perchloride of lead, but acts directly upon the platina,
it produces, if that metal be used, a solution of
chloride of platina in the chloride of lead; in consequence
of which a portion of platina can pass to the cathode,
and would then produce a vitiated result. I therefore
sought for, and found in plumbago, another substance,
which could be used safely as the positive electrode
in such bodies as chlorides, iodides, &c.
The chlorine or iodine does not act
upon it, but is evolved in the free state; and the
plumbago has no re-action, under the circumstances,
upon the fused chloride or iodide in which it is plunged.
Even if a few particles of plumbago should separate
by the heat or the mechanical action of the evolved
gas, they can do no harm in the chloride.
795. The mean of three experiments
gave the number of 100.85 as the equivalent for lead.
The chemical equivalent is 103.5. The deficiency
in my experiments I attribute to the solution of part
of the gas (716.) in the volta-electrometer;
but the results leave no doubt on my mind that both
the lead and the chlorine are, in this case, evolved
in definite quantities by the action of a given
quantity of electricity (814. &c.).
796. Chloride of antimony.—It
was in endeavouring to obtain the electro-chemical
equivalent of antimony from the chloride, that I found
reasons for the statement I have made respecting the
presence of water in it in an earlier part of these
Researches (690. 693. &c.).
797. I endeavoured to experiment
upon the oxide of lead obtained by fusion and
ignition of the nitrate in a platina crucible, but
found great difficulty, from the high temperature
required for perfect fusion, and the powerful fluxing
qualities of the substance. Green-glass tubes
repeatedly failed. I at last fused the oxide
in a small porcelain crucible, heated fully in a charcoal
fire; and, as it is was essential that the evolution
of the lead at the cathode should take place
beneath the surface, the negative electrode was guarded
by a green-glass tube, fused around it in such a manner
as to expose only the knob of platina at the lower
end (fi.), so that it could be plunged beneath
the surface, and thus exclude contact of air or oxygen
with the lead reduced there. A platina wire was
employed for the positive electrode, that metal not
being subject to any action from the oxygen evolved
against it. The arrangement is given in fi.
798. In an experiment of this
kind the equivalent for the lead came out 93.17, which
is very much too small. This, I believe, was because
of the small interval between the positive and negative
electrodes in the oxide of lead; so that it was not
unlikely that some of the froth and bubbles formed
by the oxygen at the anode should occasionally
even touch the lead reduced at the cathode,
and re-oxidize it. When I endeavoured to correct
this by having more litharge, the greater heat required
to keep it all fluid caused a quicker action on the
crucible, which was soon eaten through, and the experiment
stopped.
799. In one experiment of this
kind I used borate of lead (408. 673.). It evolves
lead, under the influence of the electric current,
at the anode, and oxygen at the cathode;
and as the boracic acid is not either directly (408.)
or incidentally decomposed during the operation, I
expected a result dependent on the oxide of lead.
The borate is not so violent a flux as the oxide,
but it requires a higher temperature to make it quite
liquid; and if not very hot, the bubbles of oxygen
cling to the positive electrode, and retard the transfer
of electricity. The number for lead came out 101.29,
which is so near to 103.5 as to show that the action
of the current had been definite.
800. Oxide of bismuth.—I
found this substance required too high a temperature,
and acted too powerfully as a flux, to allow of any
experiment being made on it, without the application
of more time and care than I could give at present.
801. The ordinary protoxide
of antimony, which consists of one proportional
of metal and one and a half of oxygen, was subjected
to the action of the electric current in a green-glass
tube (789.), surrounded by a jacket of platina foil,
and heated in a charcoal fire. The decomposition
began and proceeded very well at first, apparently
indicating, according to the general law (679. 697.),
that this substance was one containing such elements
and in such proportions as made it amenable to the
power of the electric current. This effect I
have already given reasons for supposing may be due
to the presence of a true protoxide, consisting of
single proportionals (696. 693.). The action
soon diminished, and finally ceased, because of the
formation of a higher oxide of the metal at the positive
electrode. This compound, which was probably the
peroxide, being infusible and insoluble in the protoxide,
formed a crystalline crust around the positive electrode;
and thus insulating it, prevented the transmission
of the electricity. Whether, if it had been fusible
and still immiscible, it would have decomposed, is
doubtful, because of its departure from the required
composition (697.). It was a very natural secondary
product at the positive electrode (779.). On
opening the tube it was found that a little antimony
had been separated at the negative electrode; but the
quantity was too small to allow of any quantitative
result being obtained.
802. Iodide of lead.—This
substance can be experimented with in tubes heated
by a spirit-lamp (789.); but I obtained no good results
from it, whether I used positive electrodes of platina
or plumbago. In two experiments the numbers for
the lead came out only 75.46 and 73.45, instead of
103.5. This I attribute to the formation of a
periodide at the positive electrode, which, dissolving
in the mass of liquid iodide, came in contact with
the lead evolved at the negative electrode, and dissolved
part of it, becoming itself again protiodide.
Such a periodide does exist; and it is very rarely
that the iodide of lead formed by precipitation, and
well-washed, can be fused without evolving much iodine,
from the presence of this percompound; nor does crystallization
from its hot aqueous solution free it from this substance.
Even when a little of the protiodide and iodine are
merely rubbed together in a mortar, a portion of the
periodide is formed. And though it is decomposed
by being fused and heated to dull redness for a few
minutes, and the whole reduced to protiodide, yet that
is not at all opposed to the possibility, that a little
of that which is formed in great excess of iodine
at the anode, should be carried by the rapid
currents in the liquid into contact with the cathode.
803. This view of the result
was strengthened by a third experiment, where the
space between the electrodes was increased to one third
of an inch; for now the interfering effects were much
diminished, and the number of the lead came out 89.04;
and it was fully confirmed by the results obtained
in the cases of transfer to be immediately
described (818.).
The experiments on iodide of lead
therefore offer no exception to the general law
under consideration, but on the contrary may, from
general considerations, be admitted as included in
it.
804. Protiodide of tin.—This
substance, when fused (402.), conducts and is decomposed
by the electric current, tin is evolved at the anode,
and periodide of tin as a secondary result (779. 790.)
at the cathode. The temperature required
for its fusion is too high to allow of the production
of any results fit for weighing.
805. Iodide of potassium was
subjected to electrolytic action in a tube, like that
in fi. (789.). The negative electrode was
a globule of lead, and I hoped in this way to retain
the potassium, and obtain results that could be weighed
and compared with the volta-electrometer indication;
but the difficulties dependent upon the high temperature
required, the action upon the glass, the fusibility
of the platina induced by the presence of the lead,
and other circumstances, prevented me from procuring
such results. The iodide was decomposed with
the evolution of iodine at the anode, and of
potassium at the cathode, as in former cases.
806. In some of these experiments
several substances were placed in succession, and
decomposed simultaneously by the same electric current:
thus, protochloride of tin, chloride of lead, and water,
were thus acted on at once. It is needless to
say that the results were comparable, the tin, lead,
chlorine, oxygen, and hydrogen evolved being definite
in quantity and electro-chemical equivalents to
each other.
807. Let us turn to another kind
of proof of the definite chemical action of electricity.
If any circumstances could be supposed to exert an
influence over the quantity of the matters evolved
during electrolytic action, one would expect them
to be present when electrodes of different substances,
and possessing very different chemical affinities for
such matters, were used. Platina has no power
in dilute sulphuric acid of combining with the oxygen
at the anode, though the latter be evolved in
the nascent state against it. Copper, on the other
hand, immediately unites with the oxygen, as the electric
current sets it free from the hydrogen; and zinc is
not only able to combine with it, but can, without
any help from the electricity, abstract it directly
from the water, at the same time setting torrents
of hydrogen free. Yet in cases where these three
substances were used as the positive electrodes in
three similar portions of the same dilute sulphuric
acid, specific gravity 1.336, precisely the same quantity
of water was decomposed by the electric current, and
precisely the same quantity of hydrogen set free at
the cathodes of the three solutions.
808. The experiment was made
thus. Portions of the dilute sulphuric acid were
put into three basins. Three volta-electrometer
tubes, of the form fig. 62. were filled with
the same acid, and one inverted in each basin (707.).
A zinc plate, connected with the positive end of a
voltaic battery, was dipped into the first basin,
forming the positive electrode there, the hydrogen,
which was abundantly evolved from it by the direct
action of the acid, being allowed to escape. A
copper plate, which dipped into the acid of the second
basin, was connected with the negative electrode of
the first basin; and a platina plate, which
dipped into the acid of the third basin, was connected
with the negative electrode of the second basin.
The negative electrode of the third basin was connected
with a volta-electrometer (711.), and that with
the negative end of the voltaic battery.
809. Immediately that the circuit
was complete, the electro-chemical action commenced
in all the vessels. The hydrogen still rose in,
apparently, undiminished quantities from the positive
zinc electrode in the first basin. No oxygen
was evolved at the positive copper electrode in the
second basin, but a sulphate of copper was formed there;
whilst in the third basin the positive platina electrode
evolved pure oxygen gas, and was itself unaffected.
But in all the basins the hydrogen liberated
at the negative platina electrodes was the
same in quantity, and the same with the volume
of hydrogen evolved in the volta-electrometer,
showing that in all the vessels the current had decomposed
an equal quantity of water. In this trying case,
therefore, the chemical action of electricity
proved to be perfectly definite.
810. A similar experiment was
made with muriatic acid diluted with its bulk of water.
The three positive electrodes were zinc, silver, and
platina; the first being able to separate and combine
with the chlorine without the aid of the current;
the second combining with the chlorine only after the
current had set it free; and the third rejecting almost
the whole of it. The three negative electrodes
were, as before, platina plates fixed within glass
tubes. In this experiment, as in the former, the
quantity of hydrogen evolved at the cathodes
was the same for all, and the same as the hydrogen
evolved in the volta-electrometer. I have
already given my reasons for believing that in these
experiments it is the muriatic acid which is directly
decomposed by the electricity (764.); and the results
prove that the quantities so decomposed are perfectly
definite and proportionate to the quantity of
electricity which has passed.
811. In this experiment the chloride
of silver formed in the second basin retarded the
passage of the current of electricity, by virtue of
the law of conduction before described (394.), so
that it had to be cleaned off four or five times during
the course of the experiment; but this caused no difference
between the results of that vessel and the others.
812. Charcoal was used as the
positive electrode in both sulphuric and muriatic
acids (808. 810.); but this change produced no variation
of the results. A zinc positive electrode, in
sulphate of soda or solution of common salt, gave
the same constancy of operation.
813. Experiments of a similar
kind were then made with bodies altogether in a different
state, i.e. with fused chlorides, iodides,
&c. I have already described an experiment with
fused chloride of silver, in which the electrodes
were of metallic silver, the one rendered negative
becoming increased and lengthened by the addition
of metal, whilst the other was dissolved and eaten
away by its abstraction. This experiment was repeated,
two weighed pieces of silver wire being used as the
electrodes, and a volta-electrometer included
in the circuit. Great care was taken to withdraw
the negative electrodes so regularly and steadily that
the crystals of reduced silver should not form a metallic
communication beneath the surface of the fused chloride.
On concluding the experiment the positive electrode
was re-weighed, and its loss ascertained. The
mixture of chloride of silver, and metal, withdrawn
in successive portions at the negative electrode,
was digested in solution of ammonia, to remove the
chloride, and the metallic silver remaining also weighed:
it was the reduction at the cathode, and exactly
equalled the solution at the anode; and each
portion was as nearly as possible the equivalent to
the water decomposed in the volta-electrometer.
814. The infusible condition
of the silver at the temperature used, and the length
and ramifying character of its crystals, render the
above experiment difficult to perform, and uncertain
in its results. I therefore wrought with chloride
of lead, using a green-glass tube, formed as in fi. A weighed platina wire was fused into the
bottom of a small tube, as before described (789.).
The tube was then bent to an angle, at about half an
inch distance from the closed end; and the part between
the angle and the extremity being softened, was forced
upward, as in the figure, so as to form a bridge,
or rather separation, producing two little depressions
or basins a, b, within the tube. This
arrangement was suspended by a platina wire, as before,
so that the heat of a spirit-lamp could be applied
to it, such inclination being given to it as would
allow all air to escape during the fusion of the chloride
of lead. A positive electrode was then provided,
by bending up the end of a platina wire into a knot,
and fusing about twenty grains of metallic lead on
to it, in a small closed tube of glass, which was
afterwards broken away. Being so furnished, the
wire with its lead was weighed, and the weight recorded.
815. Chloride of lead was now
introduced into the tube, and carefully fused.
The leaded electrode was also introduced; after which
the metal, at its extremity, soon melted. In
this state of things the tube was filled up to c
with melted chloride of lead; the end of the electrode
to be rendered negative was in the basin b,
and the electrode of melted lead was retained in the
basin a, and, by connexion with the proper conducting
wire of a voltaic battery, was rendered positive.
A volta-electrometer was included in the circuit.
816. Immediately upon the completion
of the communication with the voltaic battery, the
current passed, and decomposition proceeded. No
chlorine was evolved at the positive electrode; but
as the fused chloride was transparent, a button of
alloy could be observed gradually forming and increasing
in size at b, whilst the lead at a could
also be seen gradually to diminish. After a time,
the experiment was stopped; the tube allowed to cool,
and broken open; the wires, with their buttons, cleaned
and weighed; and their change in weight compared with
the indication of the volta-electrometer.
817. In this experiment the positive
electrode had lost just as much lead as the negative
one had gained (795.), and the loss and gain were very
nearly the equivalents of the water decomposed in the
volta-electrometer, giving for lead the number
101.5. It is therefore evident, in this instance,
that causing a strong affinity, or no affinity,
for the substance evolved at the anode, to
be active during the experiment (807.), produces no
variation in the definite action of the electric current.
818. A similar experiment was
then made with iodide of lead, and in this manner
all confusion from the formation of a periodide avoided
(803.). No iodine was evolved during the whole
action, and finally the loss of lead at the anode
was the same as the gain at the cathode, the
equivalent number, by comparison with the result in
the volta-electrometer, being 103.5.
819. Then protochloride of tin
was subjected to the electric current in the same
manner, using of course, a tin positive electrode.
No bichloride of tin was now formed (779. 790.).
On examining the two electrodes, the positive had
lost precisely as much as the negative had gained;
and by comparison with the volta-electrometer,
the number for tin came out 59.
820. It is quite necessary in
these and similar experiments to examine the interior
of the bulbs of alloy at the ends of the conducting
wires; for occasionally, and especially with those
which have been positive, they are cavernous, and
contain portions of the chloride or iodide used, which
must be removed before the final weight is ascertained.
This is more usually the case with lead than tin.
821. All these facts combine
into, I think, an irresistible mass of evidence, proving
the truth of the important proposition which I at first
laid down, namely, that the chemical power of a
current of electricity is in direct proportion to
the absolute quantity of electricity which passes
(377. 783.). They prove, too, that this is not
merely true with one substance, as water, but generally
with all electrolytic bodies; and, further, that the
results obtained with any one substance do not
merely agree amongst themselves, but also with those
obtained from other substances, the whole combining
together into one series of definite electro-chemical
actions (505.). I do not mean to say that
no exceptions will appear: perhaps some may arise,
especially amongst substances existing only by weak
affinity; but I do not expect that any will seriously
disturb the result announced. If, in the well-considered,
well-examined, and, I may surely say, well-ascertained
doctrines of the definite nature of ordinary chemical
affinity, such exceptions occur, as they do in abundance,
yet, without being allowed to disturb our minds as
to the general conclusion, they ought also to be allowed
if they should present themselves at this, the opening
of a new view of electro-chemical action; not being
held up as obstructions to those who may be engaged
in rendering that view more and more perfect, but
laid aside for a while, in hopes that their perfect
and consistent explanation will ultimately appear.
822. The doctrine of definite
electro-chemical action just laid down, and, I
believe, established, leads to some new views of the
relations and classifications of bodies associated
with or subject to this action. Some of these
I shall proceed to consider.
823. In the first place, compound
bodies may be separated into two great classes, namely,
those which are decomposable by the electric current,
and those which are not: of the latter, some
are conductors, others non-conductors, of voltaic
electricity. The former do not depend for
their decomposability upon the nature of their elements
only; for, of the same two elements, bodies may be
formed, of which one shall belong to one class and
another to the other class; but probably on the proportions
also (697.). It is further remarkable, that with
very few, if any, exceptions (414. 691.), these decomposable
bodies are exactly those governed by the remarkable
law of conduction I have before described (694.); for
that law does not extend to the many compound fusible
substances that are excluded from this class.
I propose to call bodies of this, the decomposable
class, Electrolytes (664.).
824. Then, again, the substances
into which these divide, under the influence of the
electric current, form an exceedingly important general
class. They are combining bodies; are directly
associated with the fundamental parts of the doctrine
of chemical affinity; and have each a definite proportion,
in which they are always evolved during electrolytic
action. I have proposed to call these bodies generally
ions, or particularly anions and cations,
according as they appear at the anode or cathode
(665.); and the numbers representing the proportions
in which they are evolved electro-chemical equivalents.
Thus hydrogen, oxygen, chlorine, iodine, lead, tin
are ions; the three former are anions,
the two metals are cations, and 1, 8, 3, 125,
104, 58, are their electro-chemical equivalents
nearly.
825. A summary of certain points
already ascertained respecting electrolytes, ions,
and electro-chemical equivalents, may be given
in the following general form of propositions, without,
I hope, including any serious error.
826. i. A single ion,
i.e. one not in combination with another, will
have no tendency to pass to either of the electrodes,
and will be perfectly indifferent to the passing current,
unless it be itself a compound of more elementary
ions, and so subject to actual decomposition.
Upon this fact is founded much of the proof adduced
in favour of the new theory of electro-chemical decomposition,
which I put forth in a former series of these Researches
(518. &c.).
827. ii. If one ion be
combined in right proportions (697.) with another
strongly opposed to it in its ordinary chemical relations,
i.e. if an anion be combined with a cation,
then both will travel, the one to the anode,
the other to the cathode, of the decomposing
body (530, 542. 547.).
828. iii. If, therefore, an ion
pass towards one of the electrodes, another ion
must also be passing simultaneously to the other electrode,
although, from secondary action, it may not make its
appearance (743.).
829. iv. A body decomposable
directly by the electric current, i.e. an electrolyte,
must consist of two ions, and must also render
them up during the act of decomposition.
830. v. There is but one electrolyte
composed of the same two elementary ions; at
least such appears to be the fact (697.), dependent
upon a law, that only single electro-chemical equivalents
of elementary ions can go to the electrodes, and not
multiples.
831. vi. A body not decomposable
when alone, as boracic acid, is not directly decomposable
by the electric current when in combination (780.).
It may act as an ion going wholly to the anode
or cathode, but does not yield up its elements,
except occasionally by a secondary action. Perhaps
it is superfluous for me to point out that this proposition
has no relation to such cases as that of water,
which, by the presence of other bodies, is rendered
a better conductor of electricity, and therefore
is more freely decomposed.
832. vii. The nature of the substance
of which the electrode is formed, provided it be a
conductor, causes no difference in the electro-decomposition,
either in kind or degree (807. 813.): but it
seriously influences, by secondary action (714.), the
state in which the finally appear. Advantage
may be taken of this principle in combining and ions
collecting such ions as, if evolved in their
free state, would be unmanageable.
833. viii. A substance which,
being used as the electrode, can combine with the
ion evolved against it, is also, I believe,
an ion, and combines, in such cases, in the
quantity represented by its electro-chemical equivalent.
All the experiments I have made agree with this view;
and it seems to me, at present, to result as a necessary
consequence. Whether, in the secondary actions
that take place, where the ion acts, not upon
the matter of the electrode, but on that which is
around it in the liquid (744.), the same consequence
follows, will require more extended investigation
to determine.
834. ix. Compound ions
are not necessarily composed of electro-chemical equivalents
of simple ions. For instance, sulphuric
acid, boracic acid, phosphoric acid, are ions,
but not electrolytes, i.e. not composed
of electro-chemical equivalents of simple ions.
835. x. Electro-chemical equivalents
are always consistent; i.e. the same number which
represents the equivalent of a substance A when it
is separating from a substance B, will also represent
A when separating from a third substance C. Thus,
8 is the electro-chemical equivalent of oxygen, whether
separating from hydrogen, or tin, or lead; and 103.5
is the electrochemical equivalent of lead, whether
separating from oxygen, or chlorine, or iodine.
836. xi. Electro-chemical equivalents
coincide, and are the same, with ordinary chemical
equivalents.
837. By means of experiment and
the preceding propositions, a knowledge of ions
and their electro-chemical equivalents may be obtained
in various ways.
838. In the first place, they
may be determined directly, as has been done with
hydrogen, oxygen, lead, and tin, in the numerous experiments
already quoted.
839. In the next place, from
propositions ii. and iii., may be deduced the knowledge
of many other ions, and also their equivalents.
When chloride of lead was decomposed, platina being
used for both electrodes (395.), there could remain
no more doubt that chlorine was passing to the anode,
although it combined with the platina there, than when
the positive electrode, being of plumbago (794.),
allowed its evolution in the free state; neither could
there, in either case, remain any doubt that for every
103.5 parts of lead evolved at the cathode,
36 parts of chlorine were evolved at the anode,
for the remaining chloride of lead was unchanged.
So also, when in a metallic solution one volume of
oxygen, or a secondary compound containing that proportion,
appeared at the anode, no doubt could arise
that hydrogen, equivalent to two volumes, had been
determined to the cathode, although, by a secondary
action, it had been employed in reducing oxides of
lead, copper, or other metals, to the metallic state.
In this manner, then, we learn from the experiments
already described in these Researches, that chlorine,
iodine, bromine, fluorine, calcium, potassium, strontium,
magnesium, manganese, &c., are ions and that
their electro-chemical equivalents are the
same as their ordinary chemical equivalents.
840. Propositions iv. and v.
extend our means of gaining information. For
if a body of known chemical composition is found to
be decomposable, and the nature of the substance evolved
as a primary or even a secondary result (743. 777.)
at one of the electrodes, be ascertained, the electro-chemical
equivalent of that body may be deduced from the known
constant composition of the substance evolved.
Thus, when fused protiodide of tin is decomposed by
the voltaic current (804.), the conclusion may be drawn,
that both the iodine and tin are ions, and
that the proportions in which they combine in the
fused compound express their electro-chemical equivalents.
Again, with respect to the fused iodide of potassium
(805.), it is an electrolyte; and the chemical equivalents
will also be the electro-chemical equivalents.
841. If proposition viii. sustain
extensive experimental investigation, then it will
not only help to confirm the results obtained by the
use of the other propositions, but will give abundant
original information of its own.
842. In many instances, the secondary
results obtained by the action of the evolved
ion on the substances present in the surrounding
liquid or solution, will give the electro-chemical
equivalent. Thus, in the solution of acetate
of lead, and, as far as I have gone, in other proto-salts
subjected to the reducing action of the nascent hydrogen
at the cathode, the metal precipitated has
been in the same quantity as if it had been a primary
product, (provided no free hydrogen escaped there,)
and therefore gave accurately the number representing
its electro-chemical equivalent.
843. Upon this principle it is
that secondary results may occasionally be used as
measurers of the volta-electric current (706.
740.); but there are not many metallic solutions that
answer this purpose well: for unless the metal
is easily precipitated, hydrogen will be evolved at
the cathode and vitiate the result. If
a soluble peroxide is formed at the anode, or
if the precipitated metal crystallize across the solution
and touch the positive electrode, similar vitiated
results are obtained. I expect to find in some
salts, as the acétates of mercury and zinc, solutions
favourable for this use.
844. After the first experimental
investigations to establish the definite chemical
action of electricity, I have not hesitated to apply
the more strict results of chemical analysis to correct
the numbers obtained as electrolytic results.
This, it is evident, may be done in a great number
of cases, without using too much liberty towards the
due severity of scientific research. The series
of numbers representing electro-chemical equivalents
must, like those expressing the ordinary equivalents
of chemically acting bodies, remain subject to the
continual correction of experiment and sound reasoning.
845. I give the following brief
Table of ions and their electro-chemical equivalents,
rather as a specimen of a first attempt than as anything
that can supply the want which must very quickly be
felt, of a full and complete tabular account of this
class of bodies. Looking forward to such a table
as of extreme utility (if well-constructed) in developing
the intimate relation of ordinary chemical affinity
to electrical actions, and identifying the two, not
to the imagination merely, but to the conviction of
the senses and a sound judgement, I may be allowed
to express a hope, that the endeavour will always
be to make it a table of real, and not hypothetical,
electro-chemical equivalents; for we shall else overrun
the facts, and lose all sight and consciousness of
the knowledge lying directly in our path.
846. The equivalent numbers do
not profess to be exact, and are taken almost entirely
from the chemical results of other philosophers in
whom I could repose more confidence, as to these points,
than in myself.
848. This Table might be further
arrange into groups of such substances as either act
with, or replace, each other. Thus, for instance,
acids and bases act in relation to each other; but
they do not act in association with oxygen, hydrogen,
or elementary substances. There is indeed little
or no doubt that, when the electrical relations of
the particles of matter come to be closely examined,
this division must be made. The simple substances,
with cyanogen, sulpho-cyanogen, and one or two other
compound bodies, will probably form the first group;
and the acids and bases, with such analogous compounds
as may prove to be ions, the second group.
Whether these will include all ions, or whether
a third class of more complicated results will be
required, must be decided by future experiments.
849. It is probable that
all our present elementary bodies are ions,
but that is not as yet certain. There are some,
such as carbon, phosphorus, nitrogen, silicon, boron,
alumium, the right of which to the title of ion
it is desirable to decide as soon as possible.
There are also many compound bodies, and amongst them
alumina and silica, which it is desirable to class
immediately by unexceptionable experiments. It
is also possible, that all combinable bodies,
compound as well as simple, may enter into the class
of ions; but at present it does not seem to
me probable. Still the experimental evidence
I have is so small in proportion to what must gradually
accumulate around, and bear upon, this point, that
I am afraid to give a strong opinion upon it.
850. I think I cannot deceive
myself in considering the doctrine of definite electro-chemical
action as of the utmost importance. It touches
by its facts more directly and closely than any former
fact, or set of facts, have done, upon the beautiful
idea, that ordinary chemical affinity is a mere consequence
of the electrical attractions of the particles of
different kinds of matter; and it will probably lead
us to the means by which we may enlighten that which
is at present so obscure, and either fully demonstrate
the truth of the idea, or develope that which ought
to replace it.
851. A very valuable use of electro-chemical
equivalents will be to decide, in cases of doubt,
what is the true chemical equivalent, or definite
proportional, or atomic number of a body; for I have
such conviction that the power which governs electro-decomposition
and ordinary chemical attractions is the same; and
such confidence in the overruling influence of those
natural laws which render the former definite, as to
feel no hesitation in believing that the latter must
submit to them also. Such being the case, I can
have, no doubt that, assuming hydrogen as 1, and dismissing
small fractions for the simplicity of expression, the
equivalent number or atomic weight of oxygen is 8,
of chlorine 36, of bromine 78.4, of lead 103.5, of
tin 59, &c., notwithstanding that a very high authority
doubles several of these numbers.
S 13. On the absolute quantity
of Electricity associated with the particles or atoms
of Matter.
852. The theory of definite electrolytical
or electro-chemical action appears to me to touch
immediately upon the absolute quantity of electricity
or electric power belonging to different bodies.
It is impossible, perhaps, to speak on this point
without committing oneself beyond what present facts
will sustain; and yet it is equally impossible, and
perhaps would be impolitic, not to reason upon the
subject. Although we know nothing of what an
atom is, yet we cannot resist forming some idea of
a small particle, which represents it to the mind;
and though we are in equal, if not greater, ignorance
of electricity, so as to be unable to say whether
it is a particular matter or matters, or mere motion
of ordinary matter, or some third kind of power or
agent, yet there is an immensity of facts which justify
us in believing that the atoms of matter are in some
way endowed or associated with electrical powers, to
which they owe their most striking qualities, and
amongst them their mutual chemical affinity.
As soon as we perceive, through the teaching of Dalton,
that chemical powers are, however varied the circumstances
in which they are exerted, definite for each body,
we learn to estimate the relative degree of force
which resides in such bodies: and when upon that
knowledge comes the fact, that the electricity, which
we appear to be capable of loosening from its habitation
for a while, and conveying from place to place, whilst
it retains its chemical force, can be measured
out, and being so measured is found to be as definite
in its action as any of those portions which,
remaining associated with the particles of matter,
give them their chemical relation; we seem
to have found the link which connects the proportion
of that we have evolved to the proportion of that belonging
to the particles in their natural state.
853. Now it is wonderful to observe
how small a quantity of a compound body is decomposed
by a certain portion of electricity. Let us, for
instance, consider this and a few other points in
relation to water. One grain of water, acidulated
to facilitate conduction, will require an electric
current to be continued for three minutes and three
quarters of time to effect its decomposition, which
current must be powerful enough to retain a platina
wire 1/104 of an inch in thickness, red-hot, in
the air during the whole time; and if interrupted
anywhere by charcoal points, will produce a very brilliant
and constant star of light. If attention be paid
to the instantaneous discharge of electricity of tension,
as illustrated in the beautiful experiments of Mr.
Wheatstone, and to what I have said elsewhere on
the relation of common and voltaic electricity (371.
375.), it will not be too much to say that this necessary
quantity of electricity is equal to a very powerful
flash of lightning. Yet we have it under perfect
command; can evolve, direct, and employ it at pleasure;
and when it has performed its full work of electrolyzation,
it has only separated the elements of a single
grain of water.
854. On the other hand, the relation
between the conduction of the electricity and the
decomposition of the water is so close, that one cannot
take place without the other. If the water is
altered only in that small degree which consists in
its having the solid instead of the fluid state, the
conduction is stopped, and the decomposition is stopped
with it. Whether the conduction be considered
as depending upon the decomposition, or not (443.
703.), still the relation of the two functions is equally
intimate and inseparable.
855. Considering this close and
twofold relation, namely, that without decomposition
transmission of electricity does not occur; and, that
for a given definite quantity of electricity passed,
an equally definite and constant quantity of water
or other matter is decomposed; considering also that
the agent, which is electricity, is simply employed
in overcoming electrical powers in the body subjected
to its action; it seems a probable, and almost a natural
consequence, that the quantity which passes is the
equivalent of, and therefore equal to, that
of the particles separated; i.e. that if the
electrical power which holds the elements of a grain
of water in combination, or which makes a grain of
oxygen and hydrogen in the right proportions unite
into water when they are made to combine, could be
thrown into the condition of a current, it would
exactly equal the current required for the separation
of that grain of water into its elements again.
856. This view of the subject
gives an almost overwhelming idea of the extraordinary
quantity or degree of electric power which naturally
belongs to the particles of matter; but it is not
inconsistent in the slightest degree with the facts
which can be brought to bear on this point. To
illustrate this I must say a few words on the voltaic
pile.
857. Intending hereafter to apply
the results given in this and the preceding series
of Researches to a close investigation of the source
of electricity in the voltaic instrument, I have refrained
from forming any decided opinion on the subject; and
without at all meaning to dismiss metallic contact,
or the contact of dissimilar substances, being conductors,
but not metallic, as if they had nothing to do with
the origin of the current,
I still am fully of opinion with Davy,
that it is at least continued by chemical action,
and that the supply constituting the current is almost
entirely from that source.
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 attention
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
connected, that one cannot happen without the other.
This I have shown abundantly in water, and numerous
other cases (402. 476.). If, then, a voltaic trough
have its extremities connected by a body capable of
being decomposed, as water, we shall have a continuous
current through the apparatus; and whilst it remains
in this state we may look at the part where the acid
is acting upon the plates, and that where the current
is acting upon the water, as the reciprocals of each
other. In both parts we have the two conditions
inseparable in such bodies as these, namely,
the passing of a current, and decomposition; and this
is as true of the cells in the battery as of the water
cell; for no voltaic battery has as yet been constructed
in which the chemical action is only that of combination:
decomposition is always included, and is, I
believe, an essential chemical part.
859. But the difference in the
two parts of the connected battery, that is, the decomposition
or experimental cell, and the acting cells, is simply
this. In the former we urge the current through,
but it, apparently of necessity, is accompanied by
decomposition: in the latter we cause decompositions
by ordinary chemical actions, (which are, however,
themselves electrical,) and, as a consequence, have
the electrical current; and as the decomposition dependent
upon the current is definite in the former case, so
is the current associated with the decomposition also
definite in the latter (862. &c.).
860. Let us apply this in support
of what I have surmised respecting the enormous electric
power of each particle or atom of matter (856.).
I showed in a former series of these Researches on
the relation by measure of common and voltaic electricity,
that two wires, one of platina and one of zinc, each
one-eighteenth of an inch in diameter, placed five-sixteenths
of an inch apart, and immersed to the depth of five-eighths
of an inch in acid, consisting of one drop of oil
of vitriol and four ounces of distilled water at a
temperature of about 60 deg. Fahr., and connected
at the other extremities by a copper wire eighteen
feet long, and one-eighteenth of an inch in thickness,
yielded as much electricity in little more than three
seconds of time as a Leyden battery charged by thirty
turns of a very large and powerful plate electric
machine in full action (371.). This quantity,
though sufficient if passed at once through the head
of a rat or cat to have killed it, as by a flash of
lightning, was evolved by the mutual action of so
small a portion of the zinc wire and water in contact
with it, that the loss of weight sustained by either
would be inappreciable by our most delicate instruments;
and as to the water which could be decomposed by that
current, it must have been insensible in quantity,
for no trace of hydrogen appeared upon the surface
of the platina during those three seconds.
861. What an enormous quantity
of electricity, therefore, is required for the decomposition
of a single grain of water! We have already seen
that it must be in quantity sufficient to sustain
a platina wire 1/104 of an inch in thickness, red-hot,
in contact with the air, for three minutes and three
quarters (853.), a quantity which is almost infinitely
greater than that which could be evolved by the little
standard voltaic arrangement to which I have just
referred (860. 871.). I have endeavoured to make
a comparison by the loss of weight of such a wire
in a given time in such an acid, according to a principle
and experiment to be almost immediately described
(862.); but the proportion is so high that I am almost
afraid to mention it. It would appear that 800,000
such charges of the Leyden battery as I have referred
to above, would be necessary to supply electricity
sufficient to decompose a single grain of water; or,
if I am right, to equal the quantity of electricity
which is naturally associated with the elements of
that grain of water, endowing them with their mutual
chemical affinity.
862. In further proof of this
high electric condition of the particles of matter,
and the identity as to quantity of that belonging
to them with that necessary for their separation,
I will describe an experiment of great simplicity
but extreme beauty, when viewed in relation to the
evolution of an electric current and its decomposing
powers.
863. A dilute sulphuric acid,
made by adding about one part by measure of oil of
vitriol to thirty parts of water, will act energetically
upon a piece of zinc plate in its ordinary and simple
state: but, as Mr. Sturgeon has shown, not
at all, or scarcely so, if the surface of the metal
has in the first instance been amalgamated; yet the
amalgamated zinc will act powerfully with platina
as an electromotor, hydrogen being evolved on
the surface of the latter metal, as the zinc is oxidized
and dissolved. The amalgamation is best effected
by sprinkling a few drops of mercury upon the surface
of the zinc, the latter being moistened with the dilute
acid, and rubbing with the fingers or two so as to
extend the liquid metal over the whole of the surface.
Any mercury in excess, forming liquid drops upon the
zinc, should be wiped off.
864. Two plates of zinc thus
amalgamated were dried and accurately weighed; one,
which we will call A, weighed 163.1 grains; the other,
to be called B, weighed 148.3 grains. They were
about five inches long, and 0.4 of an inch wide.
An earthenware pneumatic trough was filled with dilute
sulphuric acid, of the strength just described (863.),
and a gas jar, also filled with the acid, inverted
in it. A plate of platina of nearly the same
length, but about three times as wide as the zinc plates,
was put up into this jar. The zinc plate A was
also introduced into the jar, and brought in contact
with the platina, and at the same moment the plate
B was put into the acid of the trough, but out of
contact with other metallic matter.
865. Strong action immediately
occurred in the jar upon the contact of the zinc and
platina plates. Hydrogen gas rose from the platina,
and was collected in the jar, but no hydrogen or other
gas rose from either zinc plate. In about
ten or twelve minutes, sufficient hydrogen having been
collected, the experiment was stopped; during its progress
a few small bubbles had appeared upon plate B, but
none upon plate A. The plates were washed in distilled
water, dried, and reweighed. Plate B weighed 148.3
grains, as before, having lost nothing by the direct
chemical action of the acid. Plate A weighed
154.65 grains, 8.45 grains of it having been oxidized
and dissolved during the experiment.
866. The hydrogen gas was next
transferred to a water-trough and measured; it amounted
to 12.5 cubic inches, the temperature being 52 deg.,
and the barometer 29.2 inches. This quantity,
corrected for temperature, pressure, and moisture,
becomes 12.15453 cubic inches of dry hydrogen at mean
temperature and pressure; which, increased by one half
for the oxygen that must have gone to the anode,
i.e. to the zinc, gives 18.232 cubic inches as
the quantity of oxygen and hydrogen evolved from the
water decomposed by the electric current. According
to the estimate of the weight of the mixed gas before
adopted (791.), this volume is equal to 2.3535544 grains,
which therefore is the weight of water decomposed;
and this quantity is to 8.45, the quantity of zinc
oxidized, as 9 is to 32.31. Now taking 9 as the
equivalent number of water, the number 32.5 is given
as the equivalent number of zinc; a coincidence sufficiently
near to show, what indeed could not but happen, that
for an equivalent of zinc oxidized an equivalent of
water must be decomposed.
867. But let us observe how
the water is decomposed. It is electrolyzed,
i.e. is decomposed voltaically, and not in the
ordinary manner (as to appearance) of chemical decompositions;
for the oxygen appears at the anode and the
hydrogen at the cathode of the body under decomposition,
and these were in many parts of the experiment above
an inch asunder. Again, the ordinary chemical
affinity was not enough under the circumstances to
effect the decomposition of the water, as was abundantly
proved by the inaction on plate B; the voltaic current
was essential. And to prevent any idea that the
chemical affinity was almost sufficient to decompose
the water, and that a smaller current of electricity
might, under the circumstances, cause the hydrogen
to pass to the cathode, I need only refer to
the results which I have given (807. 813.) to shew
that the chemical action at the electrodes has not
the slightest influence over the quantities
of water or other substances decomposed between them,
but that they are entirely dependent upon the quantity
of electricity which passes.
868. What, then, follows as a
necessary consequence of the whole experiment?
Why, this: that the chemical action upon 32.31
parts, or one equivalent of zinc, in this simple voltaic
circle, was able to evolve such quantity of electricity
in the form of a current, as, passing through water,
should decompose 9 parts, or one equivalent of that
substance: and considering the definite relations
of electricity as developed in the preceding parts
of the present paper, the results prove that the quantity
of electricity which, being naturally associated with
the particles of matter, gives them their combining
power, is able, when thrown into a current, to separate
those particles from their state of combination; or,
in other words, that the electricity which decomposes,
and that which is evolved by the decomposition of
a certain quantity of matter, are alike.
869. The harmony which this theory
of the definite evolution and the equivalent definite
action of electricity introduces into the associated
theories of definite proportions and electrochemical
affinity, is very great. According to it, the
equivalent weights of bodies are simply those quantities
of them which contain equal quantities of electricity,
or have naturally equal electric powers; it being
the ELECTRICITY which determines the equivalent
number, because it determines the combining
force. Or, if we adopt the atomic theory or phraseology,
then the atoms of bodies which are equivalents to
each other in their ordinary chemical action, have
equal quantities of electricity naturally associated
with them. But I must confess I am jealous of
the term atom; for though it is very easy to
talk of atoms, it is very difficult to form a clear
idea of their nature, especially when compound bodies
are under consideration.
870. I cannot refrain from recalling
here the beautiful idea put forth, I believe, by Berzelius
(703.) in his development of his views of the electro-chemical
theory of affinity, that the heat and light evolved
during cases of powerful combination are the consequence
of the electric discharge which is at the moment taking
place. The idea is in perfect accordance with
the view I have taken of the quantity of electricity
associated with the particles of matter.
871. In this exposition of the
law of the definite action of electricity, and its
corresponding definite proportion in the particles
of bodies, I do not pretend to have brought, as yet,
every case of chemical or electro-chemical action
under its dominion. There are numerous considerations
of a theoretical nature, especially respecting the
compound particles of matter and the resulting electrical
forces which they ought to possess, which I hope will
gradually receive their development; and there are
numerous experimental cases, as, for instance, those
of compounds formed by weak affinities, the simultaneous
decomposition of water and salts, &c., which still
require investigation. But whatever the results
on these and numerous other points may be, I do not
believe that the facts which I have advanced, or even
the general laws deduced from them, will suffer any
serious change; and they are of sufficient importance
to justify their publication, though much may yet
remain imperfect or undone. Indeed, it is the
great beauty of our science, CHEMISTRY, that advancement
in it, whether in a degree great or small, instead
of exhausting the subjects of research, opens the
doors to further and more abundant knowledge, overflowing
with beauty and utility, to those who will be at the
easy personal pains of undertaking its experimental
investigation.
872. The definite production
of electricity (868.) in association with its definite
action proves, I think, that the current of electricity
in the voltaic pile: is sustained by chemical
decomposition, or rather by chemical action, and not
by contact only. But here, as elsewhere (857.),
I beg to reserve my opinion as to the real action
of contact, not having yet been able to make up my
mind as to whether it is an exciting cause of the
current, or merely necessary to allow of the conduction
of electricity, otherwise generated, from one metal
to the other.
873. But admitting that chemical
action is the source of electricity, what an infinitely
small fraction of that which is active do we obtain
and employ in our voltaic batteries! Zinc and
platina wires, one-eighteenth of an inch in diameter
and about half an inch long, dipped into dilute sulphuric
acid, so weak that it is not sensibly sour to the tongue,
or scarcely to our most delicate test-papers, will
evolve more electricity in one-twentieth of a minute
(860.) than any man would willingly allow to pass
through his body at once. The chemical action
of a grain of water upon four grains of zinc can evolve
electricity equal in quantity to that of a powerful
thunder-storm (868. 861.). Nor is it merely true
that the quantity is active; it can be directed and
made to perform its full equivalent duty (867. &c.).
Is there not, then, great reason to hope and believe
that, by a closer experimental investigation
of the principles which govern the development and
action of this subtile agent, we shall be able to increase
the power of our batteries, or invent new instruments
which shall a thousandfold surpass in energy those
which we at present possess?
874. Here for a while I must
leave the consideration of the definite chemical
action of electricity. But before I dismiss
this series of experimental Researches, I would call
to mind that, in a former series, I showed the current
of electricity was also definite in its magnetic
action (216. 366. 367. 376. 377.); and, though
this result was not pursued to any extent, I have
no doubt that the success which has attended the development
of the chemical effects is not more than would accompany
an investigation of the magnetic phenomena.
Royal Institution, December 31st,
1833.
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