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Avogadro constant

 
Wikipedia: Avogadro constant
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Values of NA[1] Units
6.022 141 79(30) × 1023 mol−1
2.731 597 57(14) × 1026 lb-mol.−1
1.707 248 479(85) × 1025 oz-mol.−1
For details, see Terminology and units below.

The Avogadro constant (symbols: L, NA) is the number of "elementary entities" (usually atoms or molecules) in one mole, that is (from the definition of the mole), the number of atoms in exactly 12 grams of carbon-12.[2][3] It was originally called Avogadro's number. The 2006 CODATA recommended value is[1]:

N_{\rm A}=6.022\ 141\ 79(30)\times 10^{23}\ \mbox{mol}^{-1}

The Avogadro constant is named after the early nineteenth century Italian scientist Amedeo Avogadro, 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.[4] The French physicist Jean Perrin in 1909 proposed naming the constant in honour of Avogadro.[5] Perrin would win the 1926 Nobel Prize in Physics, in a large part for his work in determining the Avogadro constant by several different methods.[6]

The value of the Avogadro constant was first indicated by Johann Josef Loschmidt who, in 1865, estimated the average diameter of the molecules in air by a method that is equivalent to calculating the number of particles in a given volume of gas.[7] This latter value, the number density of particles in an ideal gas, is now called the Loschmidt constant in his honour, and is approximately proportional to the Avogadro constant. The connection with Loschmidt is the root of the symbol L sometimes used for the Avogadro constant, and German language literature may refer to both constants by the same name, distinguished only by the units of measurement.[8]

Contents

Terminology and units

Perrin originally proposed the name "Avogadro's number" (N) to refer to the number of molecules in one gram-molecule of oxygen (exactly 32 grams of oxygen, according to the definitions of the period),[5] and this term is still widely used, especially in introductory works.[9] The change in name to "Avogadro constant" (NA) came with the introduction of the mole as a separate base unit in the International System of Units (SI) in 1971,[10] which recognised amount of substance as an independent dimension of measurement.[11] With this recognition, the Avogadro constant was no longer a pure number but a physical quantity associated with a unit of measurement, the reciprocal mole (mol−1) in SI units.[11] The change in name from the possessive form "Avogadro's" to the nominative form "Avogadro" is a general change in practice since Perrin's time for the names of all physical constants.[1] In effect, the constant is named in honour of Avogadro: he does not own it, and it would have been impossible to measure it during Avogadro's lifetime.

While it is rare to use units of amount of substance other than the mole, the Avogadro constant can also be defined in units such as the pound mole (lb-mol.) and the ounce mole (oz-mol.).

NA = 2.731 597 57(14) × 1026 lb-mol.−1 = 1.707 248 479(85) × 1025 oz-mol.−1

Additional physical relations

Because of its role as a scaling factor, the Avogadro constant provides the link between a number of useful physical constants when moving between the atomic scale and the macroscopic scale. For example, it provides the relationship between:

R = k_{\rm B} N_{\rm A} = 8.314\,472(15)\ {\rm J\,mol^{-1}\,K^{-1}}\,
in J mol−1 K−1
F = N_{\rm A} e = 96\,485.3383(83)\ {\rm C\,mol^{-1}} \,
in C mol−1

The Avogadro constant also enters into the definition of the unified atomic mass unit, u:

1\ {\rm u} = \frac{M_{\rm u}}{N_{\rm A}} = 1.660 \, 538\, 782(83)\times 10^{-24}\ {\rm g}

where Mu is the molar mass constant.

Measurement

Coulometry

The earliest accurate method to measure the value of the Avogadro constant was based on coulometry. The principle is to measure the Faraday constant, F, which is the electric charge carried by one mole of electrons, and to divide by the elementary charge, e, to obtain the Avogadro constant.

N_{\rm A} = \frac{F}{e}

The classic experiment is that of Bowers and Davis at NIST,[12] and relies on dissolving silver metal away from the anode of an electrolysis cell, while passing a constant electric current I for a known time t. If m is the mass of silver lost from the anode and Ar the atomic weight of silver, then the Faraday constant is given by:

F = \frac{A_{\rm r}M_{\rm u}It}{m}

The NIST workers devised an ingenious method to compensate for silver that was lost from the anode for mechanical reasons, and conducted an isotope analysis of their silver to determine the appropriate atomic weight. Their value for the conventional Faraday constant is F90 = 96 485.39(13) C/mol, which corresponds to a value for the Avogadro constant of 6.022 1449(78) × 1023 mol–1: both values have a relative standard uncertainty of 1.3 × 10–6.

Electron mass method (CODATA)

The CODATA value for the Avogadro constant[13] is determined from the ratio of the molar mass of the electron Ar(e)Mu to the rest mass of the electron me:

N_{\rm A} = \frac{A_{\rm r}({\rm e})M_{\rm u}}{m_{\rm e}}

The "relative atomic mass" of the electron, Ar(e), is a directly-measured quantity, and the molar mass constant, Mu, is a defined constant in the SI system. The electron rest mass, however, is calculated from other measured constants:[13]

m_{\rm e} = \frac{2R_{\infty}h}{c\alpha^2}

As can be seen from the table of 2006 CODATA values below,[1] the main limiting factor in the accuracy to which the value of the Avogadro constant is known is the uncertainty in the value of the Planck constant, as all the other constants which contribute to the calculation are known much more accurately.

Constant Symbol 2006 CODATA value Relative standard uncertainty Correlation coefficient
with NA
Electron relative atomic mass Ar(e) 5.485 799 0943(23) × 10–4 4.2 × 10–10 0.0082
Molar mass constant Mu 0.001 kg/mol defined
Rydberg constant R 10 973 731.568 527(73) m–1 6.6 × 10–12 0.0000
Planck constant h 6.626 068 96(33) × 10–34 Js 5.0 × 10–8 –0.9996
Speed of light c 299 792 458 m/s defined
Fine structure constant α 7.297 352 5376(50) × 10–3 6.8 × 10–10 0.0269
Avogadro constant NA 6.022 141 79(30) × 1023 mol–1 5.0 × 10–8 1

X-ray crystal density method

Ball-and-stick model of the unit cell of silicon. X-ray diffraction experiments can determine the cell parameter, a, which can in turn be used to calculate a value for Avogadro's constant

One modern method to calculate the Avogadro constant is to use ratio of the molar volume, Vm, to the unit cell volume, Vcell, for a single crystal of silicon:[14]

N_{\rm A} = \frac{8V_{\rm m}({\rm Si})}{V_{\rm cell}}

The factor of eight arises because there are eight silicon atoms in each unit cell.

The unit cell volume can be obtained by X-ray crystallography; as the unit cell is cubic, the volume is the cube of the length of one side (known as the unit cell parameter, a. In practice, measurements are carried out on a distance known as d220(Si), which is the distance between the planes denoted by the Miller indices {220}, and is equal to a/√8. The 2006 CODATA value for d220(Si) is 192.015 5762(50) pm, a relative uncertainty of 2.8 × 10–8, corresponding to a unit cell volume of 1.601 933 04(13) × 10–28 m3.

The isotope proportional composition of the sample used must be measured and taken into account. Silicon occurs with three stable isotopes – 28Si, 29Si, 30Si – and the natural variation in their proportions is greater than other uncertainties in the measurements. The atomic weight Ar for the sample crystal can be calculated, as the relative atomic masses of the three nuclides are known with great accuracy. This, together with the measured density ρ of the sample, allows the molar volume Vm to be found by:

V_{\rm m} = \frac{A_{\rm r}M_{\rm u}}{\rho}

where Mu is the molar mass constant. The 2006 CODATA value for the molar volume of silicon is 12.058 8349(11) cm3mol−1, with a relative standard uncertainty of 9.1 × 10–8.[15]

As of the 2006 CODATA recommended values, the relative uncertainty in determinations of the Avogadro constant by the X-ray crystal density method is 1.2 × 10–7, about two and a half times higher than that of the electron mass method.

See also

References and notes

  1. ^ a b c d Mohr, Peter J.; Taylor, Barry N.; Newell, David B. (2008). "CODATA Recommended Values of the Fundamental Physical Constants: 2006". Rev. Mod. Phys. 80: 633–730. doi:10.1103/RevModPhys.80.633. http://physics.nist.gov/cuu/Constants/codata.pdf.  Direct link to value.
  2. ^ International Union of Pure and Applied Chemistry (1993). Quantities, Units and Symbols in Physical Chemistry, 2nd edition, Oxford: Blackwell Science. ISBN 0-632-03583-8. Electronic version.. International Union of Pure and Applied Chemistry Commission on Quantities and Units in Clinical Chemistry; International Federation of Clinical Chemistry Committee on Quantities and Units (1996), "Glossary of Terms in Quantities and Units in Clinical Chemistry (IUPAC-IFCC Recommendations 1996)" (PDF), Pure Appl. Chem. 68: 957–1000, doi:10.1351/pac199668040957, http://www.iupac.org/publications/pac/1996/pdf/6804x0957.pdf, retrieved 2006-12-28 
  3. ^ International Union of Pure and Applied Chemistry Commission on Atomic Weights and Isotopic Abundances (1992). "Atomic Weight: The Name, Its History, Definition and Units" (PDF). Pure Appl. Chem. 64: 1535–43. doi:10.1351/pac199264101535. http://www.iupac.org/publications/pac/1992/pdf/6410x1535.pdf. Retrieved 2006-12-28. 
  4. ^ Avogadro, Amadeo (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.
  5. ^ a b Perrin, Jean (1909), "Mouvement brownien et réalité moléculaire", Annales de Chimie et de Physique, 8e Série 18: 1–114  Extract in English, translation by Frederick Soddy.
  6. ^ Oseen, C.W. (December 10, 1926). Presentation Speech for the 1926 Nobel Prize in Physics.
  7. ^ Loschmidt, J. (1865), "Zur Grösse der Luftmoleküle", Sitzungsberichte der kaiserlichen Akademie der Wissenschaften Wien 52 (2): 395–413  English translation.
  8. ^ Virgo, S.E. (1933), "Loschmidt's Number", Science Progress 27: 634–49, http://gemini.tntech.edu/~tfurtsch/scihist/loschmid.html 
  9. ^ See, e.g., Kotz, John C.; Treichel, Paul M.; Townsend, John R. (2008), Chemistry and Chemical Reactivity (7th ed.), Brooks/Cole, ISBN 0495387037, http://cengagesites.com/academic/kotz.cfm?site=2719&section=home 
  10. ^ Resolution 3, 14th General Conference of Weights and Measures (CGPM), 1971.
  11. ^ a b de Bièvre, P.; Peiser, H.S. (1992), "'Atomic Weight'—The Name, Its History, Definition, and Units", Pure Appl. Chem. 64 (10): 1535–43, doi:10.1351/pac199264101535, http://www.iupac.org/publications/pac/1992/pdf/6410x1535.pdf 
  12. ^ This account is based on the review in Mohr, Peter J.; Taylor, Barry N. (1999). "CODATA recommended values of the fundamental physical constants: 1998". J. Phys. Chem. Ref. Data 28 (6): 1713–1852. doi:10.1103/RevModPhys.72.351. 
  13. ^ a b Mohr, Peter J.; Taylor, Barry N. (2005). "CODATA recommended values of the fundamental physical constants: 2002". Rev. Mod. Phys. 77 (1): 1–107. doi:10.1103/RevModPhys.77.1. 
  14. ^ Mineralogy Database (2000-2005). "Unit Cell Formula". http://webmineral.com/help/CellDimensions.shtml. Retrieved 2007-12-09. 
  15. ^ Mohr, Peter J.; Taylor, Barry N.; Newell, David B. (2008). "CODATA Recommended Values of the Fundamental Physical Constants: 2006". Rev. Mod. Phys. 80: 633–730. doi:10.1103/RevModPhys.80.633. http://physics.nist.gov/cuu/Constants/codata.pdf.  Direct link to value.

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