Avogadro's number: Difference between revisions

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Because the mole and  Avogadro's number are defined in terms of the atomic mass constant (one twelfth of the mass of a <sup>12</sup>C atom), Avogadro's constant and Avogadro's number have by definition the same numerical value. In practice the two terms are used interchangeably.
Because the mole and  Avogadro's number are defined in terms of the atomic mass constant (one twelfth of the mass of a <sup>12</sup>C atom), Avogadro's constant and Avogadro's number have by definition the same numerical value. In practice the two terms are used interchangeably.
==History of Avogadro's number==
Since 1811, when [[Amedeo Avogadro]] put forward the notion that equal volumes of gas (we now know  [[ideal gas law|ideal gas]]) contain equal number of particles, increasingly sophisticated  methods  of determining Avogadro’s constant have been developed over the past 200 years. These include the kinetic theory of gases, Brownian motion, measurement of the electron charge, black-body radiation, alpha particle emission, and X-ray measurements of crystals.
Without the belief that a macroscopic substance consists of minute particles (initially called atoms, later also molecules), it does not make sense to speak of Avogadro's number.
This belief&mdash;atomism&mdash; was born in antiquity and grew further in importance with the developments of chemistry early in the 19th century. An important milestone was [[John Dalton]]’s  law of multiple proportions published in 1804.
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An important step in his analysis was that when only one combination of two elements is known it was assumed to be a binary
compound unless there was some evidence to the contrary, and from this Dalton drew
up the first table of the relative weights of atoms (taking hydrogen as unity) in 1803.
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==References==
==References==

Revision as of 06:12, 5 December 2007

Avogadro's number, NA, is defined as the number of atoms in 12 gram of carbon-12 atoms in their ground state at rest. By definition it is related to the atomic mass constant mu by the relation

The exact factor 1/1000 appears here by the historic facts that the kilogram is the unit of mass and that in chemistry the mole is preferred over the Kmole. Recall that the atomic mass constant has the mass 1 u exactly (u is the unified atomic mass unit). Avogadro's number is indeed defined as number, a dimensionless quantity. Its latest numeric value[1] is NA = 6.022 141 79 1023.

The SI definition of Avogadro's constant (also designated by NA) is: the number of entities (such as atoms, ions, or molecules) per mole. (This definition requires, of course, a definition of mole that does not rely on NA, but one that is in terms of 12C atoms). In this definition NA has dimension mol−1. The numeric value of Avogadro's constant is NA = 6.022 141 79 1023 mol−1.

Because the mole and Avogadro's number are defined in terms of the atomic mass constant (one twelfth of the mass of a 12C atom), Avogadro's constant and Avogadro's number have by definition the same numerical value. In practice the two terms are used interchangeably.

History of Avogadro's number

Since 1811, when Amedeo Avogadro put forward the notion that equal volumes of gas (we now know ideal gas) contain equal number of particles, increasingly sophisticated methods of determining Avogadro’s constant have been developed over the past 200 years. These include the kinetic theory of gases, Brownian motion, measurement of the electron charge, black-body radiation, alpha particle emission, and X-ray measurements of crystals.

Without the belief that a macroscopic substance consists of minute particles (initially called atoms, later also molecules), it does not make sense to speak of Avogadro's number. This belief—atomism— was born in antiquity and grew further in importance with the developments of chemistry early in the 19th century. An important milestone was John Dalton’s law of multiple proportions published in 1804.

References

  1. CODATA value retrieved December 4, 2007 from: constants stored at NIST