post from Science In Action
on 06 March 2005 02:13:00 PM. © Science In Action
Batteries (electrochemical cells) produce electricity by spontaneous chemical reactions. If you understand how batteries work, you understand a key part of chemistry and biochemistry. That is because batteries work by oxidation/reduction (redox) reactions, involving the transfer of electrons. All biochemical energy reactions, such as photosynthesis, chemosynthesis, respiration, phosphorilation, etc., depend on redox chemistry.
The terms used in redox chemistry are very confusing (I've never quite understood them). I'll try to line them all up so they make sense.
Electrons moving along a conductor is what we call electricity, or electric current. It can be used to generate magnetic fields (as in a motor) or heat things up (as in a light bulb), to drive other chemical reactions (e.g. electrolysis or electroplating), or for many other purposes. (What are electrons, anyway?)
Until the late 1700s nobody knew there was such a thing as electric current, or how to generate it. Electricity was all the rage, but principally static electricity (surface charges). The discharge of a static charge results in a brief current (lightning, static sparks, "shock" troops and jumping monks
), but it cannot be sustained to do useful work.
In the 1780s Dr. Luigi Galvani, at the University of Bologna, noticed that muscles could be stimulated to twitch by electric discharges or by contact with dissimilar metals. These studies suggested a connection between electricity and chemistry.
His colleague physicist Alessandro Giuseppe Antonio Volta, professor at the University of Pavia, invented the galvanic (electrochemical) cell in about 1800. A stack of discs of metal separated by blotters wet with salt water (a "Voltaic pile") generated significant current. Each element is a "cell", and a collection of cells is a "battery". Today we use the word "battery", in English, to refer to a single cell. (In French it is a "pile".) Here is what they looked like in Volta's day.
The University of Pavia
has a beautiful site showing some of Volta's apparatus.
The lead-acid battery was invented in 1859 by Gaston Plante, and the dry cell between 1867 and 1877 by George Leclanché, both of France. The alkaline cell was invented in 1914 by Thomas Edison. Dozens of other types of batteries have been developed since then. They all work by oxidation/reduction chemistry. Here are some pictures of cells of yesteryear
An electrochemical cell has three main parts: two electrodes and an electrolyte. The electrodes are the dissimilar metals mentioned above. There is an electrolyte that allows ions to move between them. Outside the cell they can be connected by a circuit through which electrons will flow.
A lemon can be used to make a simple cell. The cell has a zinc strip, a copper strip, and the acidic juice of the lemon as the electrolyte. It generates about one volt, but only a very small amount of current. (The voltage of a battery is determined by the materials used as electrodes and electrolyte.)
Lemon Cell Here is the site
this picture came from, where you can learn how to make a lemon battery.
Redox reactions happen all the time. Hydrocarbon fuels (such as methane, which was also discovered and isolated by Alessandro Volta) can react with oxygen to be oxidized to carbon dioxide and water. The carbon is oxidized, and gives up electrons, and the oxygen accepts them. Oxidation and reduction are simultaneous. The trick in a battery is to separate the oxidation from the reduction, so the electrons have to go on a trip through the external circuit, where we can make use of them.
"Oxidation" and "reduction" reactions make a battery work. Oxidation/reduction reactions are electron-transfer reactions. For a battery to work, both an oxidation and a reduction must happen. One generates electrons at one electrode, and the other uses them up at the other electrode. Each of these is called a "half reaction". If the electrodes are connected outside the cell by a circuit, electrons flow and the full reaction is completed.
Oxidation is when electrons are transferred from a substance to oxygen or some other compound. Oxidation doesn't have to involve oxygen, and can be thought of as "de-electronation."
Since electrons are negatively charged particles you can see how this might be related to electricity. Remember that electrons moving along a conductor is electric current. The electrode where oxidation (loss of electrons) takes place is called the anode. On a commercial battery it is marked as the "-" side.
Reduction is when a chemical reactant accepts electrons. It ends up with more electrons than it started with. Reduction could be called "electronation."
Summary of Battery Terms
|Gives up electrons||Accepts additional electrons|
|- (minus) side||+ (plus) side|
The substance that loses electrons is the "reducing agent" or "reductant", while the substance that gains electrons is the "oxidizing agent" or "oxidant". Anions are negative ions moving toward the anode. Cations are positive ions that move toward the cathode.
(The picture is from this site
OK, So What Makes Electrochemical Cells Work?
Different chemical reactions occur at the anode and the cathode in a cell. The reaction at the anode releases electrons, and leaves behind positively-charged ions. The reaction at the cathode soaks up electrons. Different materials have different tendencies to give up or accept electrons. By choosing the materials for the anode and the cathode carefully, cells with different properties can be designed.
The two dissimilar metals that form the electrodes of a cell have different "reduction potentials". Reduction potential expresses the tendency for a materiel to accept electrons (to be reduced). This reduction potential is expressed in volts. Explanation of "reduction potential"
. Here is a table of the reduction potentials
of various half-reactions.
Here is how the lead-acid battery in a car works:
The anode of each cell is metallic lead, Pb. The cathode is solid lead oxide, PbO2. The electrolyte is sulfuric acid, H2SO4 (which is dissociated into hydrogen (H+) ions and hydrogen sulfate (HSO4-) ions in solution.)
When electrons are allowed to flow (when the battery is under load) this reaction takes place at the anode (- side):
Lead metal is oxidized to bivalent Pb(II), giving up 2 electrons, and reacts with sulfate ion (SO42-) to form lead sulfate and a hydrogen ion:
Pb + SO4²¯ ? PbSO4 + 2e- + H+
The reduction potential of this reaction is +0.356 Volts.
Simultaneously at the cathode (+ side):
The lead in lead oxide is reduced from tetravalent Pb(IV) to bivalent Pb(II) when the lead oxide reacts with sulfate ions in the electrolyte and hydrogen ions, accepting electrons to form lead sulfate and water:
PbO2 + SO4²¯ + 4 H+ + 2 e- ? PbSO4 + H2O
The potential of this reaction is 1.685 volts.
Combined, these two half reactions make up the redox reaction
Pb + PbO2 + 2H2SO4 ? 2 PbSO4 + 2 H2O
Two electrons were liberated at the anode and flowed through the external circuit to the cathode. The total potential of the reaction is about +2 volts. A 12-volt car battery therefore has six cells in series, each contributing two volts for a total electric potential of 12 volts.This site explains the reactions
in a lead-acid cell in more detail.This site
has half-reactions and other information on all kinds of commercial batteries. Highly recommended. Check there to see how a nickel-cadmium, nickel-metal hydride, or alkaline battery works.
major sources:PowerstreamElectrochem Encyclopedia
at Case Western Reserve andElectrochemical Dictionary
at Case Western Reserve
I don't have a link to Volta's original article. Maybe you can find one:
On the Electricity Excited by the Mere Contact of Conducting Substances of Different Kinds, A. Volta, "Philosophical Transactions" Vol. 2, pp 403-431, 1800.good article on Volta and his inventioncool information about early electrical devicesbeautiful site summarizing electrochemical cell concepts
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