Amount of substance


In chemistry, the amount of substance in a given sample of matter is defined as the number of discrete atomic-scale particles in it divided by the Avogadro constant NA. In a truly atomistic view, the amount of substance is simply the number of particles that constitute the substance. The particles or entities may be molecules, atoms, ions, electrons, or other, depending on the context. The value of the Avogadro constant NA has been defined as. In the truly atomistic view, 1 mol = particles and therefore the conversion constant is simply NA = 1. The amount of substance is sometimes referred to as the chemical amount.
The mole is a unit of amount of substance in the International System of Units, defined by fixing the Avogadro constant at the given value. Historically, the mole was defined as the amount of substance in 12 grams of the carbon-12 isotope. As a consequence, the mass of one mole of a chemical compound, in grams, is numerically equal to the mass of one molecule of the compound, in daltons, and the molar mass of an isotope in grams per mole is equal to the mass number. For example, a molecule of water has a mass of about 18.015 daltons on average, whereas a mole of water has a total mass of about 18.015 grams.
In chemistry, because of the law of multiple proportions, it is often much more convenient to work with amounts of substances than with masses or volumes. For example, the chemical fact "1 molecule of oxygen will react with 2 molecules of hydrogen to make 2 molecules of water " can also be stated as "1 mole of will react with 2 moles of to form 2 moles of water". The same chemical fact, expressed in terms of masses, would be "32 g of oxygen will react with approximately 2.0156 g of hydrogen to make approximately 18.0152 g of water". In terms of volume, the numbers would depend on the pressure and temperature of the reagents and products. For the same reasons, the concentrations of reagents and products in solution are often specified in moles per liter, rather than grams per liter.
The amount of substance is also a convenient concept in thermodynamics. For example, the pressure of a certain quantity of a noble gas in a recipient of a given volume, at a given temperature, is directly related to the number of molecules in the gas, not to its mass.
This technical sense of the term "amount of substance" should not be confused with the general sense of "amount" in the English language. The latter may refer to other measurements such as mass or volume, rather than the number of particles. There are proposals to replace "amount of substance" with more easily-distinguishable terms, such as enplethy and stoichiometric amount.
The IUPAC recommends that "amount of substance" should be used instead of "number of moles", just as the quantity mass should not be called "number of kilograms".

Nature of the particles

To avoid ambiguity, the nature of the particles should be specified in any measurement of the amount of substance: thus, 1 mol of molecules of oxygen is about 32 grams, whereas 1 mol of atoms of oxygen is about 16 grams.
When not specified, the amount of a substance with discrete covalently bonded molecules of definite size, like water or ethylene, usually means the number of such molecules. For metallic elements, and some non-metallic elements like carbon and silicon which have molecules of indefinite size, it usually refers to atoms instead. For element allotropes with discrete molecules – like iodine,, chlorine,, white phosphorus, and octasulfur – the term is ambiguous, and should be clarified.
For salts and for polymers of indeterminate molecular size, the term usually refers to the number of instances of the conventional chemical formula of the substance. Thus, for example, 1 mol of calcium chloride is understood to contain one mole of calcium cations and two moles of chloride anions, even though the ions are not bound into separate three-atom molecules. Likewise, 1 mol of solid silicon dioxide n, which has a three-dimensional covalent lattice structure, is understood to contain one mole of silicon atoms and two moles of oxygen atoms.
For substances that normally exist in partially dissociated or polymerized form, the amount of substance usually refers to its nominal formula, without taking those changes into account. For example, "a solution of 1 mol of formaldehyde in water" is generally understood to contain one mole of carbon atoms, even though some of the formaldehyde may be in the form of methanediol or oligomers like paraformaldehyde and metaformaldehyde. Note that, because of the latter, the number of carbon-containing molecules in the solution may be substantially less than one mole.

Derived quantities

Molar quantities (per mole)

The quotient of some extensive physical quantity of a homogeneous sample by its amount of substance is an intensive property of the substance, usually named by the prefix molar.
For example, the ratio of the mass of a sample by its amount of substance is the molar mass, whose SI unit is kilograms per mole; which is about 18.015 g/mol for water, and 55.845 g/mol for iron. From the volume, one gets the molar volume, which is about 17.962 milliliter/mol for liquid water and 7.092 mL/mol for iron at room temperature. From the heat capacity, one gets the molar heat capacity, which is about 75.385 J/K/mol for water and about 25.10 J/K/mol for iron.

Amount concentration (moles per liter)

Another important derived quantity is the amount of substance concentration, divided by the volume of the sample.
The SI unit of this quantity is the mole per liter. Thus, for example, the amount concentration of sodium chloride in ocean water is typically about 0.599 mol/L.
The denominator is the volume of the solution, not of the solvent. Thus, for example, one liter of standard vodka contains about 0.40 L of ethanol and 0.60 L of water. The amount concentration of ethanol is therefore / = 6.85 mol/L, not /, which would be 11.4 mol/L.
In chemistry, it is customary to read the unit "mol/L" as molar, and denote it by the symbol "M". Thus, for example, each liter of a "0.5 molar" or "0.5 M" solution of urea in water contains 0.5 moles of that molecule. By extension, the amount concentration is also commonly called the molarity of the substance of interest in the solution. However, as of May 2007, these terms and symbols are not condoned by IUPAC.
This quantity should not be confused with the mass concentration, which is the mass of the substance of interest divided by the volume of the solution.

Amount fraction (moles per mole)

Confusingly, the amount concentration, or "molarity", should also be distinguished from "molar concentration", which should be the number of moles of the substance of interest divided by the total number of moles in the solution sample. This quantity is more properly called the amount fraction.

History

The alchemists, and especially the early metallurgists, probably had some notion of amount of substance, but there are no surviving records of any generalization of the idea beyond a set of recipes. In 1758, Mikhail Lomonosov questioned the idea that mass was the only measure of the quantity of matter, but he did so only in relation to his theories on gravitation. The development of the concept of amount of substance was coincidental with, and vital to, the birth of modern chemistry.