The Avogadro constant, commonly denoted NA[1] or L,[2] is an SI defining constant with an exact value of 6.02214076×1023 mol−1 (reciprocal moles).[3][4] It is this defined number of constituent particles (usually molecules, atoms, ions, or ion pairs—in general, entities) per mole (SI unit) and used as a normalization factor in relating the amount of substance, n(X), in a sample of a substance X to the corresponding number of entities, N(X): n(X) = N(X)(1/NA), an aggregate of N(X) reciprocal Avogadro constants. By setting N(X) = 1, a reciprocal Avogadro constant is seen to be equal to one entity, which means that n(X) is more easily interpreted as an aggregate of N(X) entities. In the SI dimensional analysis of measurement units, the dimension of the Avogadro constant is the reciprocal of amount of substance, denoted N−1. The Avogadro number, sometimes denoted N0,[5][6] is the numeric value of the Avogadro constant (i.e., without a unit), namely the dimensionless number6.02214076×1023; the value chosen based on the number of atoms in 12 grams of carbon-12 in alignment with the historical definition of a mole.[1][7] The constant is named after the Italian physicist and chemist Amedeo Avogadro (1776–1856).
The Avogadro constant NA is also the factor that converts the average mass () of one particle, in grams, to the molar mass () of the substance, in grams per mole (g/mol).[8] That is, .
The constant NA also relates the molar volume (the volume per mole) of a substance to the average volume nominally occupied by one of its particles, when both are expressed in the same units of volume. For example, since the molar volume of water in ordinary conditions is about 18 mL/mol, the volume occupied by one molecule of water is about 18/(6.022×1023) mL, or about 0.030 nm3 (cubic nanometres). For a crystalline substance, N0 relates the volume of a crystal with one mole worth of repeating unit cells, to the volume of a single cell (both in the same units).
Definition
The Avogadro constant was historically derived from the old definition of the mole as the amount of substance in 12 grams of carbon-12 (12C); or, equivalently, the number of daltons in a gram, where the dalton is defined as 1/12 of the mass of a 12C atom.[9] By this old definition, the numerical value of the Avogadro constant in mol−1 (the Avogadro number) was a physical constant that had to be determined experimentally.
The redefinition of the mole in 2019, as being the amount of substance containing exactly 6.02214076×1023 particles,[7] meant that the mass of 1 mole of a substance is now exactly the product of the Avogadro number and the average mass of its particles. The dalton, however, is still defined as 1/12 of the mass of a 12C atom, which must be determined experimentally and is known only with finite accuracy. The prior experiments that aimed to determine the Avogadro constant are now re-interpreted as measurements of the value in grams of the dalton.
By the old definition of mole, the numerical value of one mole of a substance, expressed in grams, was precisely equal to the average mass of one particle in daltons. With the new definition, this numerical equivalence is no longer exact, as it is affected by the uncertainty of the value of the dalton in SI units. However, it is still applicable for all practical purposes. For example, the average mass of one molecule of water is about 18.0153 daltons, and of one mole of water is about 18.0153 grams. Also, the Avogadro number is the approximate number of nucleons (protons and neutrons) in one gram of ordinary matter.
The Avogadro constant is named after the Italian scientist Amedeo Avogadro (1776–1856), who, in 1811, first proposed that the volume of a gas (at a given pressure and temperature) is proportional to the number of atoms or molecules regardless of the nature of the gas.[12]
The name Avogadro's number was coined in 1909 by the physicist Jean Perrin, who defined it as the number of molecules in exactly 32 grams of oxygen gas.[14] The goal of this definition was to make the mass of a mole of a substance, in grams, be numerically equal to the mass of one molecule relative to the mass of the hydrogen atom; which, because of the law of definite proportions, was the natural unit of atomic mass, and was assumed to be 1/16 of the atomic mass of oxygen.
First measurements
The value of Avogadro's number (not yet known by that name) was first obtained indirectly by Josef Loschmidt in 1865, by estimating the number of particles in a given volume of gas.[15] This value, the number densityn0 of particles in an ideal gas, is now called the Loschmidt constant in his honor, and is related to the Avogadro constant, NA, by
where p0 is the pressure, R is the gas constant, and T0 is the absolute temperature. Because of this work, the symbol L is sometimes used for the Avogadro constant,[16] and, in German literature, that name may be used for both constants, distinguished only by the units of measurement.[17] (However, NA should not be confused with the entirely different Loschmidt constant in English-language literature.)
Perrin himself determined the Avogadro number by several different experimental methods. He was awarded the 1926 Nobel Prize in Physics, largely for this work.[18]
By this definition, one mole of any substance contained exactly as many elementary entities as one mole of any other substance. However, this number N0 was a physical constant that had to be experimentally determined since it depended on the mass (in grams) of one atom of 12C, and therefore, it was known only to a limited number of decimal digits.[16] The common rule of thumb that "one gram of matter contains N0 nucleons" was exact for carbon-12, but slightly inexact for other elements and isotopes.
In the same conference, the BIPM also named NA (the factor that converted moles into number of particles) the "Avogadro constant". However, the term "Avogadro number" continued to be used, especially in introductory works.[20] As a consequence of this definition, NA was not a pure number, but had the metric dimension of reciprocal of amount of substance (mol−1).
In its 26th Conference, the BIPM adopted a different approach: effective 20 May 2019, it defined the Avogadro constant NA as the exact value 6.02214076×1023 mol−1, thus redefining the mole as exactly 6.02214076×1023 constituent particles of the substance under consideration.[21][7] One consequence of this change is that the mass of a mole of 12C atoms is no longer exactly 0.012 kg. On the other hand, the dalton (a.k.a. universal atomic mass unit) remains unchanged as 1/12 of the mass of 12C.[22][23] Thus, the molar mass constant remains very close to but no longer exactly equal to 1 g/mol, although the difference (4.5×10−10 in relative terms, as of March 2019) is insignificant for all practical purposes.[7][1]
Connection to other constants
The Avogadro constant NA is related to other physical constants and properties.
^H. P. Lehmann, X. Fuentes-Arderiu, and L. F. Bertello (1996): "Glossary of terms in quantities and units in Clinical Chemistry (IUPAC-IFCC Recommendations 1996)"; p. 963, item "Avogadro constant". Pure and Applied Chemistry, vol. 68, iss. 4, pp. 957–1000. doi:10.1351/pac199668040957
^Marvin Yelles (1971): McGraw-Hill Encyclopedia of Science and Technology, Vol. 9, 3rd ed.; 707 pages. ISBN978-0070797987
^Avogadro, Amedeo (1811). "Essai d'une maniere de determiner les masses relatives des molecules elementaires des corps, et les proportions selon lesquelles elles entrent dans ces combinaisons". Journal de Physique. 73: 58–76. English translation.