Electrolysis is the passing of a
direct electric current through an
electrolyte which is producing chemical reactions at the
electrodes and
decomposition of the materials. The main components required to achieve electrolysis are an
electrolyte, electrodes, and an external power source. A partition (e.g. an
ion-exchange membrane or a
salt bridge) is optional to keep the products from diffusing to the vicinity of the opposite electrode. The electrolyte is a
chemical substance which contains
free ions and carries
electric current (e.g. an ion-conducting
polymer, solution, or an
ionic liquid compound). If the ions are not mobile, as in most solid
salts, then electrolysis cannot occur. A liquid electrolyte is produced by: •
Solvation or reaction of an
ionic compound with a
solvent (such as water) to produce mobile ions • An ionic compound melted by heating The electrodes are immersed separated by a distance such that a current flows between them through the
electrolyte and are connected to the power source which completes the
electrical circuit. A
direct current supplied by the power source drives the reaction causing ions in the electrolyte to be attracted toward the respective oppositely charged electrode. Electrodes of
metal,
graphite and
semiconductor material are widely used. Choice of suitable
electrode depends on chemical reactivity between the electrode and electrolyte and manufacturing cost. Historically, when non-reactive anodes were desired for electrolysis, graphite (called plumbago in Faraday's time) or platinum were chosen. They were found to be some of the least reactive materials for anodes. Platinum erodes very slowly compared to other materials, and graphite crumbles and can produce carbon dioxide in aqueous solutions but otherwise does not participate in the reaction. Cathodes may be made of the same material, or they may be made from a more reactive one since anode wear is greater due to oxidation at the anode.
Process of electrolysis The key process of electrolysis is the interchange of atoms and ions by the removal or addition of electrons due to the applied potential. The desired products of electrolysis are often in a different physical state from the electrolyte and can be removed by mechanical processes (e.g. by collecting gas above an electrode or precipitating a product out of the electrolyte). The quantity of the products is proportional to the current, and when two or more electrolytic cells are connected in series to the same power source, the products produced in the cells are proportional to their
equivalent weight. These are known as
Faraday's laws of electrolysis. Each electrode attracts ions that are of the opposite
charge. Positively charged ions (
cations) move towards the electron-providing (negative) cathode. Negatively charged ions (
anions) move towards the electron-extracting (positive) anode. In this process
electrons are effectively introduced at the cathode as a
reactant and removed at the anode as a
product. In chemistry, the loss of electrons is called
oxidation, while electron gain is called
reduction. When neutral atoms or molecules, such as those on the surface of an electrode, gain or lose electrons they become ions and may dissolve in the electrolyte and react with other ions. When ions gain or lose electrons and become neutral, they will form compounds that separate from the electrolyte. Positive metal ions like Cu2+ deposit onto the cathode in a layer. The terms for this are
electroplating,
electrowinning, and
electrorefining. When an ion gains or loses electrons without becoming neutral, its electronic charge is altered in the process. For example, the
electrolysis of brine produces hydrogen and chlorine gases which bubble from the electrolyte and are collected. The initial overall reaction is thus: :2 NaCl + 2 H2O → 2 NaOH + H2 + Cl2 The reaction at the anode results in chlorine gas from chlorine ions: :2 Cl− → Cl2 + 2 e− The reaction at the cathode results in hydrogen gas and hydroxide ions: :2 H2O + 2 e− → H2 + 2 OH− Without a partition between the electrodes, the OH− ions produced at the cathode are free to diffuse throughout the electrolyte to the anode. As the electrolyte becomes more
basic due to the production of OH−, less Cl2 emerges from the solution as it begins to react with the hydroxide producing
hypochlorite (ClO−) at the anode: :Cl2 + 2 NaOH → NaCl + NaClO + H2O The more opportunity the Cl2 has to interact with NaOH in the solution, the less Cl2 emerges at the surface of the solution and the faster the production of hypochlorite progresses. This depends on factors such as solution temperature, the amount of time the Cl2 molecule is in contact with the solution, and concentration of NaOH. Likewise, as hypochlorite increases in concentration, chlorates are produced from them: : 3 NaClO → NaClO3 + 2 NaCl Other reactions occur, such as the
self-ionization of water and the decomposition of hypochlorite at the cathode, the rate of the latter depends on factors such as
diffusion and the surface area of the cathode in contact with the electrolyte.
Decomposition potential Decomposition potential or decomposition voltage refers to the minimum voltage (difference in
electrode potential) between
anode and
cathode of an electrolytic cell that is needed for electrolysis to occur. The voltage at which electrolysis is thermodynamically preferred is the difference of the electrode potentials as calculated using the
Nernst equation. Applying additional voltage, referred to as
overpotential, can increase the rate of reaction and is often needed above the thermodynamic value. It is especially necessary for electrolysis reactions involving gases, such as
oxygen,
hydrogen or
chlorine.
Oxidation and reduction at the electrodes Oxidation of ions or neutral molecules occurs at the
anode. For example, it is possible to oxidize ferrous ions to ferric ions at the anode: : Fe(aq) → Fe(aq) + e−
Reduction of ions or neutral molecules occurs at the
cathode. It is possible to reduce
ferricyanide ions to
ferrocyanide ions at the cathode: :Fe(CN) + e− → Fe(CN) Neutral molecules can also react at either of the electrodes. For example:
p-benzoquinone can be reduced to hydroquinone at the cathode: : + 2 e− + 2 H+ → In the last example, H+ ions (hydrogen ions) also take part in the reaction and are provided by the acid in the solution, or by the solvent itself (water, methanol, etc.). Electrolysis reactions involving H+ ions are fairly common in acidic solutions. In aqueous alkaline solutions, reactions involving OH− (hydroxide ions) are common. Sometimes the solvents themselves (usually water) are oxidized or reduced at the electrodes. It is even possible to have electrolysis involving gases, e.g. by using a
gas diffusion electrode.
Energy changes during electrolysis 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
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 and heat energy is absorbed. This heat is absorbed from the surroundings, and the
heating value of the produced hydrogen is higher than the electric input.
Variations Pulsating current results in products different from DC. For example, pulsing increases the ratio of
ozone to oxygen produced at the anode in the electrolysis of an aqueous acidic solution such as dilute sulphuric acid. Electrolysis of ethanol with pulsed current evolves an aldehyde instead of primarily an acid.
Related processes Galvanic cells and
batteries use spontaneous, energy-releasing
redox reactions to generate an electrical potential that provides useful power. When a
secondary battery is charged, its redox reaction is run in reverse and the system can be considered as an
electrolytic cell. == Industrial uses ==