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| {{about|the chemical process|the cosmetic hair removal procedure|Electrology}}
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| [[File:Electrolysis Apparatus.png|thumb|Illustration of an electrolysis apparatus used in a school laboratory.]]
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| In [[chemistry]] and [[manufacturing]], '''electrolysis''' is a method of using a [[Direct current|direct]] [[electric current]] (DC) to drive an otherwise non-spontaneous chemical reaction. Electrolysis is commercially highly important as a stage in the [[#Industrial uses|separation]] of [[chemical element|elements]] from naturally occurring sources such as [[ores]] using an [[electrolytic cell]].
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| ==History==
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| The word electrolysis comes from the [[Greek language|Greek]] {{lang|grc|ἤλεκτρον}} {{IPA-el|ɛ̌ːlektron|}} "amber" and ''{{lang|grc|λύσις}}'' {{IPA-el|lýsis|}} "dissolution".
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| *1785 – [[Martinus van Marum]]'s electrostatic generator was used to reduce [[tin]], [[zinc]], and [[antimony]] from their salts using electrolysis.<ref>The Supplement (1803 edition) to Encyclopedia Britannica 3rd edition (1797), volume 1, page 225, "Mister Van Marum, by means of his great electrical machine, decomposed the calces of tin, zinc, and antimony, and resolved them into their respective metals and oxygen" and gives as a reference Journal de Physiques, 1785.</ref>
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| *1800 – [[William Nicholson (chemist)|William Nicholson]] and [[Anthony Carlisle]] (view also [[Johann Ritter]]), decomposed [[water]] into [[hydrogen]] and [[oxygen]].
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| *1807 – [[Potassium]], [[sodium]], [[barium]], [[calcium]] and [[magnesium]] were discovered by [[Sir_Humphry_Davy#Electrolysis|Sir Humphry Davy]] using electrolysis.
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| *1875 – [[Paul Émile Lecoq de Boisbaudran]] discovered [[gallium]] using electrolysis.<ref>{{cite book|author=Sir William Crookes|title=The Chemical news and journal of industrial science; with which is incorporated the "Chemical gazette.": A journal of practical chemistry in all its applications to pharmacy, arts and manufactures|url=http://books.google.com/books?id=XgDOAAAAMAAJ&pg=PA294|accessdate=27 February 2011|year=1875|publisher=Chemical news office.|pages=294–}}</ref>
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| *1886 – [[Fluorine]] was discovered by [[Henri Moissan]] using electrolysis.
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| *1886 – [[Hall-Héroult process]] developed for making [[aluminium]]
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| *1890 – [[Castner-Kellner process]] developed for making [[sodium hydroxide]]
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| ==Overview==
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| Electrolysis is the passage of a [[Direct current|direct]] [[electric current]] through an [[ion]]ic substance that is either molten or dissolved in a suitable solvent, resulting in chemical reactions at the electrodes and separation of materials.
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| The main components required to achieve electrolysis are :
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| *An [[electrolyte]] : a [[Chemical substance|substance]] containing free [[ion]]s which are the carriers of [[electric current]] in the [[electrolyte]]. If the [[ion]]s are not mobile, as in a [[Salt (chemistry)|solid salt]] then electrolysis cannot occur.
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| *A [[direct current]] (DC) supply : provides the [[energy]] necessary to create or discharge the [[ion]]s in the [[electrolyte]]. Electric current is carried by [[electron]]s in the external circuit.
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| *Two [[electrode]]s : an [[electrical conductor]] which provides the physical interface between the [[electrical circuit]] providing the [[energy]] and the [[electrolyte]]
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| Electrodes of [[metal]], [[graphite]] and [[semiconductor]] material are widely used. Choice of suitable electrode depends on chemical reactivity between the electrode and electrolyte and the cost of manufacture.
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| ===Process of electrolysis===
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| The key process of electrolysis is the interchange of atoms and ions by the removal or addition of electrons from the external circuit. The desired products of electrolysis are often in a different physical state from the electrolyte and can be removed by some physical processes. For example, in the electrolysis of [[brine]] to produce hydrogen and chlorine, the products are gaseous. These gaseous products bubble from the electrolyte and are collected.<ref name="Tilley2004">{{cite book|author=R. J. D. Tilley|title=Understanding solids: the science of materials|url=http://books.google.com/books?id=hFZ0guoKD1QC&pg=PA281|accessdate=22 October 2011|year=2004|publisher=John Wiley and Sons|isbn=978-0-470-85276-7|pages=281–}}</ref>
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| :2 NaCl + 2 H<sub>2</sub>O → 2 NaOH + H<sub>2</sub> + Cl<sub>2</sub>
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| A liquid containing mobile ions (electrolyte) is produced by:
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| *[[Solvation]] or reaction of an [[ionic compound]] with a [[solvent]] (such as water) to produce mobile ions
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| *An ionic compound is melted (''fused'') by heating
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| An electrical potential is applied across a pair of [[electrode]]s immersed in the electrolyte. <!--
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| Many people misunderstand these definitions and think they should be the other way round. Please read the [[electrode]] article before trying to 'correct' them. Also see the [[anode]] and [[cathode]] articles. The definition is: "The anode is now defined as the electrode at which electrons leave the cell and oxidation occurs, and the cathode as the electrode at which electrons enter the cell and reduction occurs." For electrolysis, this means the anode is the positive electrode and the cathode is the negative electrode. The positively-charged ions will move towards the negative electrode, the cathode. The negatively-charged ions will move towards the positive electrode, the anode. -->
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| Each electrode attracts ions that are of the opposite [[Electric charge|charge]]. Positively charged ions ([[cation]]s) move towards the electron-providing (negative) cathode, whereas negatively charged ions ([[anion]]s) move towards the positive anode.
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| At the electrodes, [[electron]]s are absorbed or released by the atoms and ions. Those atoms that gain or lose electrons to become charged ions pass into the electrolyte. Those ions that gain or lose electrons to become uncharged atoms separate from the electrolyte. The formation of uncharged atoms from ions is called discharging.
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| The energy required to cause the ions to migrate to the electrodes, and the energy to cause the change in ionic state, is provided by the external source of electrical potential.
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| ===Oxidation and reduction at the electrodes===
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| [[Oxidation]] of ions or neutral molecules occurs at the [[anode]], and the [[Redox|reduction]] of ions or neutral molecules occurs at the [[cathode]]. For example, it is possible to oxidize ferrous ions to ferric ions at the anode:
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| :Fe{{su|p=2+|b=aq}} → Fe{{su|p=3+|b=aq}} + e<sup>–</sup>
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| It is also possible to reduce [[ferricyanide]] ions to [[ferrocyanide]] ions at the cathode:
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| :Fe(CN){{su|p=3-|b=6}} + e<sup>–</sup> → Fe(CN){{su|p=4-|b=6}}
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| Neutral molecules can also react at either of the electrodes. For example: p-Benzoquinone can be reduced to hydroquinone at the cathode:
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| [[Image:P-Benzochinon.svg|35px]] + 2 e<sup>–</sup> + 2 H<sup>+</sup> → [[Image:Hydrochinon2.svg]]
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| In the last example, H<sup>+</sup> ions (hydrogen ions) also take part in the reaction, and are provided by an acid in the solution, or the solvent itself (water, methanol etc.). Electrolysis reactions involving H<sup>+</sup> ions are fairly common in acidic solutions. In alkaline water solutions, reactions involving OH<sup>-</sup> (hydroxide ions) are common.
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| The substances oxidised or reduced can also be the solvent (usually water) or the electrodes. It is possible to have electrolysis involving gases. (Such as when using a [[Gas diffusion electrode]])
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| ===Energy changes during electrolysis===
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| The amount of electrical energy that must be added equals the change in [[Gibbs free energy]] of the reaction plus the losses in the system. The losses can (in theory) be arbitrarily close to zero, so the maximum [[thermodynamics|thermodynamic]] efficiency equals the [[enthalpy]] change divided by the free energy change of the reaction. In most cases, the electric input is larger than the enthalpy change of the reaction, so some energy is released in the form of heat. In some cases, for instance, in the electrolysis of [[steam]] into hydrogen and oxygen at high temperature, the opposite is true. Heat is absorbed from the surroundings, and the [[heating value]] of the produced hydrogen is higher than the electric input.
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| ===Related techniques===
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| The following techniques are related to electrolysis:
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| *[[Electrochemical cell]]s, including the hydrogen [[fuel cell]], utilise differences in [[Standard electrode potential]] in order to generate an electrical potential from which useful power can be extracted. Although related via the interaction of ions and electrodes, electrolysis and the operation of electrochemical cells are quite distinct. A chemical cell should ''not'' be thought of as performing "electrolysis in reverse".
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| ==Faraday's laws of electrolysis==
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| {{main|Faraday's laws of electrolysis}}
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| ===First law of electrolysis===
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| In 1832, [[Michael Faraday]] reported that the quantity of elements separated by passing an electric current through a molten or dissolved [[salt]] is proportional to the quantity of electric charge passed through the circuit. This became the basis of the first law of electrolysis:
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| :<math>m = k \cdot q</math>
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| ===Second law of electrolysis===
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| Faraday discovered that when the same amount of electricity is passed through different electrolytes/elements connected in series, the mass of substance liberated/deposited at the electrodes is directly proportional to their equivalent weights.
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| ==Industrial uses==
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| [[Image:hall-heroult-kk-2008-12-31.png|thumb|[[Hall-Heroult process]] for producing [[aluminium]]]]
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| *Production of [[aluminium]], [[lithium]], [[sodium]], [[potassium]], [[magnesium]], [[calcium]]
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| *[[Coulometry|Coulometric]] techniques can be used to determine the amount of matter transformed during electrolysis by measuring the amount of electricity required to perform the electrolysis
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| *Production of [[chlorine]] and [[sodium hydroxide]]
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| *Production of [[sodium chlorate]] and [[potassium chlorate]]
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| *Production of perfluorinated organic compounds such as [[trifluoroacetic acid]]
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| *Production of [[Copper extraction techniques#Electrorefining|electrolytic copper]] as a [[cathode]], from refined [[copper]] of lower purity as an [[anode]].
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| Electrolysis has many other uses:
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| *[[Electrometallurgy]] is the process of reduction of metals from metallic compounds to obtain the pure form of metal using electrolysis. For example, sodium hydroxide in its molten form is separated by electrolysis into sodium and oxygen, both of which have important chemical uses. (Water is produced at the same time.)
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| *[[Anodization]] is an electrolytic process that makes the surface of metals resistant to [[corrosion]]. For example, ships are saved from being corroded by oxygen in the water by this process. The process is also used to decorate surfaces.
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| *Production of [[oxygen]] for [[spacecraft]] and [[nuclear submarines]].
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| *[[Electroplating]] is used in layering metals to fortify them. Electroplating is used in many industries for functional or decorative purposes, as in vehicle bodies and nickel coins.
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| *Production of hydrogen for fuel, using a cheap source of electrical energy.
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| *Electrolytic Etching of metal surfaces like tools or knives with a permanent mark or logo.
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| Electrolysis is also used in the cleaning and preservation of old artifacts. Because the process separates the non-metallic particles from the metallic ones, it is very useful for cleaning old coins and even larger objects.
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| ==Competing half-reactions in solution electrolysis==
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| Using a cell containing inert platinum electrodes, electrolysis of aqueous solutions of some salts leads to reduction of the cations (e.g., metal deposition with, e.g., zinc salts) and oxidation of the anions (e.g. evolution of bromine with bromides). However, with salts of some metals (e.g. sodium) hydrogen is evolved at the cathode, and for salts containing some anions (e.g. sulfate SO<sub>4</sub><sup>2−</sup>) oxygen is evolved at the anode. In both cases this is due to water being reduced to form hydrogen or oxidised to form oxygen.
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| In principle the voltage required to electrolyze a salt solution can be derived from the [[standard electrode potential]] for the reactions at the anode and cathode. The [[standard electrode potential]] is directly related to the [[Gibbs free energy]], ΔG, for the reactions at each electrode and refers to an electrode with no current flowing. An extract from the [[table of standard electrode potentials]] is shown below.
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| {| cellpadding="10" class="wikitable"
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| |-
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| ! [[Half-reaction]]
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| ! ''E°'' (V)
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| ! Ref.
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| |-
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| | [[Sodium|Na]]<sup>+</sup> + ''e''<sup>−</sup> {{eqm}} Na(''s'')
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| | −2.71 ||<ref name="Atk">Peter Atkins (1997). ''Physical Chemistry'', 6th edition (W.H. Freeman and Company, New York).</ref>
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| |-
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| | [[Zinc|Zn]]<sup>2+</sup> + 2''e''<sup>−</sup> {{eqm}} Zn(''s'')
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| | −0.7618 ||<ref name="van88">Vanýsek, Petr (2007). [http://www.hbcpnetbase.com/articles/08_08_88.pdf “Electrochemical Series”], in [http://www.hbcpnetbase.com/ ''Handbook of Chemistry and Physics: 88th Edition''] (Chemical Rubber Company).</ref>
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| |-
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| | '''2H<sup>+</sup> + 2''e''<sup>−</sup> {{eqm}} H<sub>2</sub>(''g'')'''
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| | '''≡ 0'''
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| |-
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| | Br<sub>2</sub>(''aq'') + 2''e''<sup>−</sup> {{eqm}} 2Br<sup>−</sup>
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| | +1.0873 ||<ref name=van88/>
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| |-
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| | O<sub>2</sub>(''g'') + 4H<sup>+</sup> + 4''e''<sup>−</sup> {{eqm}} 2H<sub>2</sub>O
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| | +1.23 ||<ref name="Atk"/>
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| |-
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| | Cl<sub>2</sub>(''g'') + 2''e''<sup>−</sup> {{eqm}} 2Cl<sup>−</sup>
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| | +1.36 ||<ref name="Atk"/>
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| |-
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| | {{chem|S|2|O|8|<sup>2–</sup>}} + 2''e''<sup>−</sup> {{eqm}} 2{{chem|SO|4|2−}}
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| | +2.07 ||<ref name="Atk"/>
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| |}
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| In terms of electrolysis, this table should be interpreted as follows:
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|
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| * Oxidized species (often a cation) with a more negative cell potential are more difficult to reduce than oxidized species with a more positive cell potential. For example it is more difficult to reduce a sodium ion to a sodium metal than it is to reduce a zinc ion to a zinc metal.
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|
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| * Reduced species (often an anion) with a more positive cell potential are more difficult to oxidize than reduced species with a more negative cell potential. For example it is more difficult to oxidize sulfate anions than it is to oxidize bromide anions.
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|
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| Using the [[Nernst equation]] the [[electrode potential]] can be calculated for a specific concentration of ions, temperature and the number of electrons involved. For pure water ([[pH]] 7):
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| *the electrode potential for the reduction producing hydrogen is −0.41 V
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| *the electrode potential for the oxidation producing oxygen is +0.82 V.
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| Comparable figures calculated in a similar way, for 1M [[zinc bromide]], ZnBr<sub>2</sub>, are −0.76 V for the reduction to Zn metal and +1.10 V for the oxidation producing bromine.
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| The conclusion from these figures is that hydrogen should be produced at the cathode and oxygen at the anode from the electrolysis of water which is at variance with the experimental observation that zinc metal is deposited and bromine is produced.<ref>A.E. Vogel, 1951, A textbook of Quantitative Inorganic Analysis, Longmans, Green and Co</ref>
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| The explanation is that these calculated potentials only indicate the thermodynamically preferred reaction. In practice many other factors have to be taken into account such as the kinetics of some of the reaction steps involved. These factors together mean that a higher potential is required for the reduction and oxidation of water than predicted, and these are termed [[overpotential]]s. Experimentally it is known that [[overpotential]]s depend on the design of the cell and the nature of the electrodes.
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| For the electrolysis of a neutral (pH 7) sodium chloride solution, the reduction of sodium ion is thermodynamically very difficult and water is reduced evolving hydrogen leaving hydroxide ions in solution. At the anode the oxidation of chlorine is observed rather than the oxidation of water since the overpotential for the oxidation of [[chloride]] to [[chlorine]] is lower than the overpotential for the oxidation of [[water]] to [[oxygen]]. The [[hydroxide ion]]s and dissolved [[chlorine]] gas react further to form [[hypochlorous acid]]. The aqueous solutions resulting from this process is called [[electrolyzed water]] and is used as a disinfectant and cleaning agent.
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| ==Electrolysis of water==
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| <!-- Deleted image removed: [[Image:Hoffman voltameter.jpg|thumb|300px|Hofmann electrolysis apparatus used in electrolysis of water{{puic|Image:Hoffman voltameter.jpg|log=2008 April 26}}]] -->
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| {{main|Electrolysis of water}}
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| One important use of electrolysis of water is to produce [[hydrogen]].
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| :2 H<sub>2</sub>O(l) → 2 H<sub>2</sub>(g) + O<sub>2</sub>(g); E<sub>0</sub> = -1.229 V
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| Hydrogen can be used as a fuel for powering internal combustion engines by combustion or electric motors via hydrogen fuel cells (see ''[[Hydrogen vehicle]]''). This has been suggested as one approach to shift economies of the world from the current state of almost complete dependence upon hydrocarbons for energy (''See [[hydrogen economy]].'')
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| The [[Energy conversion efficiency|energy efficiency]] of water electrolysis varies widely. The efficiency of an electrolyser is a measure of the enthalpy contained in the hydrogen (to under go combustion with oxygen, or some other later reaction), compared with the input electrical energy. Heat/enthalpy values for hydrogen are well published in science and engineering texts, as 144 MJ/kg. Note that fuel cells (not electrolysers) cannot utilise this full amount of heat/enthalpy, which has led to some confusion when calculating efficiency values for both types of technology. In the reaction, some energy is lost as heat. Some reports quote efficiencies between 50% and 70% for alkaline electrolysers; however, much higher practical efficiencies are available with the use of PEM ([[polymer electrolyte membrane electrolysis|Polymer Electrolyte Membrane electrolysis]]) and catalytic technology, such as 95% efficiency.<ref name="carmo2013a">{{cite journal|last=Carmo|first=M|coauthors=Fritz D, Mergel J, Stolten D|title=A comprehensive review on PEM water electrolysis|journal=Journal of Hydrogen Energy|year=2013|doi=10.1016/j.ijhydene.2013.01.151|url=http://dx.doi.org/10.1016/j.ijhydene.2013.01.151}}</ref><ref>{{cite web
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| |title=Chapter 3: Production of Hydrogen. Part 4: Production from electricity by means of electrolysis
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| |work=HyWeb: Knowledge – Hydrogen in the Energy Sector
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| |url=http://www.hyweb.de/Knowledge/w-i-energiew-eng3.html#3.4
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| |author=Werner Zittel
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| |coauthors=Reinhold Wurster
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| |publisher=Ludwig-Bölkow-Systemtechnik GmbH
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| |date=1996-07-08
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| }}</ref>
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| In the US there is still an occasional erroneous tendency to use the 'Lower Heating Value' for efficiencies. This value (becoming obsolete) does not represent the total amount of energy within the hydrogen, hence the efficiency appears lower than when using the more accurately defined values. The theoretical maximum considers the total amount of energy required for the formation of the hydrogen and oxygen from water. Note that (in more broader contexts of energy efficiency), these values refer only to the efficiency of converting electrical energy into hydrogen's chemical energy; the energy lost in generating the electricity is not included.
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| [[NREL]] estimated that 1 kg of hydrogen (roughly equivalent to 3 kg, or 4 L, of petroleum in energy terms) could be produced by wind powered electrolysis for between $5.55 in the near term and $2.27 in the long term.<ref name='NRELElectrolysis'>{{cite web|url=http://www.nrel.gov/docs/fy06osti/39534.pdf |title=Wind Energy and Production of Hydrogen and Electricity – Opportunities for Renewable Hydrogen – Preprint |accessdate=2008-10-20 |author=J. Levene; B. Kroposki, and G. Sverdrup |date=March 2006 |format=PDF |work=National Renewable Energy Laboratory}}</ref>
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| About 4% of hydrogen gas produced worldwide is created by electrolysis, and normally used onsite. Hydrogen is used for the creation of ammonia for fertilizer via the [[Haber process]], and converting heavy petroleum sources to lighter fractions via [[hydrocracking]].
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| ==Electrocrystallization==
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| A specialized application of electrolysis involves the growth of conductive crystals on one of the electrodes from oxidized or reduced species that are generated in situ. The technique has been used to obtain single crystals of low-dimensional electrical conductors, such as [[charge-transfer salt]]s.<ref>{{cite journal|author=K. Bechgaard, K. Carneiro, F. B. Rasmusen, H. Olsen, G. Rindorf, C. S. Jacobsen, H. Pedersen, J. E. Scott|doi=10.1021/ja00399a065|title=Superconductivity in an organic solid. Synthesis, structure, and conductivity of bis(tetramethyltetraselenafulvalenium) perchlorate, (TMTSF)2ClO4|year=1981|journal=Journal of the American Chemical Society|volume=103|issue=9|pages=2440}}</ref><ref>Williams, Jack M. Highly Conducting and Superconducting Synthetic Metals. Inorganic Syntheses [Online] 2007. 26, 386–394. {{DOI|10.1002/9780470132579.ch70}}.</ref>
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| ==Experimenters==
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| Scientific pioneers of electrolysis include:
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| {{colbegin|3}}
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| *[[Antoine Lavoisier]]
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| *[[Robert Bunsen]]
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| *[[Humphry Davy]]
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| *[[Michael Faraday]]
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| *[[Paul Heroult|Paul Héroult]]
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| *[[Svante Arrhenius]]
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| *[[Adolph Wilhelm Hermann Kolbe]]
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| *[[William Nicholson (chemist)|William Nicholson]]
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| *[[Joseph Louis Gay-Lussac]]
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| *[[Alexander von Humboldt]]
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| *[[Johann Wilhelm Hittorf]]
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| {{colend}}
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| Pioneers of batteries:
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| *[[Alessandro Volta]]
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| *[[Gaston Planté]]
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| More recently, electrolysis of [[heavy water]] was performed by Fleischmann and Pons in [[Fleischmann–Pons experiment|their famous experiment]], resulting in anomalous heat generation and the discredited claim of [[cold fusion]].
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| ==See also==
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| {{commons|Electrolysis}}
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| {{colbegin|3}}
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| *[[Alkaline water electrolysis]]
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| *[[Castner-Kellner process]]
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| *[[Electrolytic cell]]
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| *[[Faraday's law of electrolysis]]
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| *[[Faraday constant]]
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| *[[Faraday efficiency]]
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| *[[Galvanoluminescence]]
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| *[[Gas cracker]]
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| *[[Hall-Héroult process]]
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| *[[High-pressure electrolysis]]
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| *[[Overpotential]]
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| *[[Patterson Power Cell]]
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| *[[Thermochemical cycle]]
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| *[[Timeline of hydrogen technologies]]
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| *[[PEM electrolysis]]
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| {{colend}}
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| ==References==
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| {{reflist|35em}}
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| {{electrolysis}}
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| [[Category:Chemical processes]]
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| [[Category:Chemistry articles needing expert attention]]
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| [[Category:Electrochemistry]]
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| [[Category:Electrolysis|*]]
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| [[Category:Hydrogen production]]
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| [[Category:Industrial processes]]
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