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Dalton (unit)

May 18, 2023

Not to be confused with Hartree atomic units.

The dalton or unified atomic mass unit (symbols: Da or u) is a non-SI unit of mass widely used in physics and chemistry. It is defined as 112 of the mass of an unbound neutral atom of carbon-12 in its nuclear and electronic ground state and at rest.[1][2] The atomic mass constant, denoted mu, is defined identically, giving mu = m(12C)/12 = 1 Da.[3]

dalton
(unified atomic mass unit)
Unit ofmass
SymbolDa or u
Named afterJohn Dalton
Conversions
1 Da or u in ...... is equal to ...
   kg   1.66053906660(50)×10−27
   mu   1
   me   1822.888486209(53)
   MeV/c2   931.49410242(28)

This unit is commonly used in physics and chemistry to express the mass of atomic-scale objects, such as atoms, molecules, and elementary particles, both for discrete instances and multiple types of ensemble averages. For example, an atom of helium-4 has a mass of 4.0026 Da. This is an intrinsic property of the isotope and all helium-4 atoms have the same mass. Acetylsalicylic acid (aspirin), C
9H
8O
4, has an average mass of approximately 180.157 Da. However, there are no acetylsalicylic acid molecules with this mass. The two most common masses of individual acetylsalicylic acid molecules are 180.0423 Da, having the most common isotopes, and 181.0456 Da, in which one carbon is carbon-13.

The molecular masses of proteins, nucleic acids, and other large polymers are often expressed with the units kilodaltons (kDa), megadaltons (MDa), etc.[4] Titin, one of the largest known proteins, has a molecular mass of between 3 and 3.7 megadaltons.[5] The DNA of chromosome 1 in the human genome has about 249 million base pairs, each with an average mass of about 650 Da, or 156 GDa total.[6]

The mole is a unit of amount of substance, widely used in chemistry and physics, which was originally defined so that the mass of one mole of a substance, measured in grams, would be numerically equal to the average mass of one of its constituent particles, measured in daltons. That is, the molar mass of a chemical compound was meant to be numerically equal to its average molecular mass. For example, the average mass of one molecule of water is about 18.0153 daltons, and one mole of water is about 18.0153 grams. A protein whose molecule has an average mass of 64 kDa would have a molar mass of 64 kg/mol. However, while this equality can be assumed for almost all practical purposes, it is now only approximate, because of the way mole was redefined on 20 May 2019.[4][1]

In general, the mass in daltons of an atom is numerically close but not exactly equal to the number of nucleons contained in its nucleus. It follows that the molar mass of a compound (grams per mole) is numerically close to the average number of nucleons contained in each molecule. By definition, the mass of an atom of carbon-12 is 12 daltons, which corresponds with the number of nucleons that it has (6 protons and 6 neutrons). However, the mass of an atomic-scale object is affected by the binding energy of the nucleons in its atomic nuclei, as well as the mass and binding energy of its electrons. Therefore, this equality holds only for the carbon-12 atom in the stated conditions, and will vary for other substances. For example, the mass of one unbound atom of the common hydrogen isotope (hydrogen-1, protium) is 1.007825032241(94) Da,[a] the mass of the proton is 1.007276466621(53) Da,[7], the mass of one free neutron is 1.00866491595(49) Da,[8] and the mass of one hydrogen-2 (deuterium) atom is 2.014101778114(122) Da.[9] In general, the difference (absolute mass excess) is less than 0.1%; exceptions include hydrogen-1 (about 0.8%), helium-3 (0.5%), lithium-6 (0.25%) and beryllium (0.14%).

The dalton differs from the unit of mass in the atomic units systems, which is the electron rest mass (me).

Energy equivalents

The atomic mass constant can also be expressed as its energy-equivalent, muc2. The 2018 CODATA recommended values are:

muc2 = 1.49241808560(45)×10−10 J[10] = 931.49410242(28) MeV[11]

The megaelectronvolt mass-equivalent (MeV/c2) is commonly used as a unit of mass in particle physics, and these values are also important for the practical determination of relative atomic masses.

History

Origin of the concept

 
Jean Perrin in 1926

The interpretation of the law of definite proportions in terms of the atomic theory of matter implied that the masses of atoms of various elements had definite ratios that depended on the elements. While the actual masses were unknown, the relative masses could be deduced from that law. In 1803 John Dalton proposed to use the (still unknown) atomic mass of the lightest atom, that of hydrogen, as the natural unit of atomic mass. This was the basis of the atomic weight scale.[12]

For technical reasons, in 1898, chemist Wilhelm Ostwald and others proposed to redefine the unit of atomic mass as 116 of the mass of an oxygen atom.[13] That proposal was formally adopted by the International Committee on Atomic Weights (ICAW) in 1903. That was approximately the mass of one hydrogen atom, but oxygen was more amenable to experimental determination. This suggestion was made before the discovery of the existence of elemental isotopes, which occurred in 1912.[12] The physicist Jean Perrin had adopted the same definition in 1909 during his experiments to determine the atomic masses and the Avogadro constant.[14] This definition remained unchanged until 1961.[15][16] Perrin also defined the "mole" as an amount of a compound that contained as many molecules as 32 grams of oxygen (O
2). He called that number the Avogadro number in honor of physicist Amedeo Avogadro.

Isotopic variation

The discovery of isotopes of oxygen in 1929 required a more precise definition of the unit. Unfortunately, two distinct definitions came into use. Chemists choose to define the AMU as 116 of the average mass of an oxygen atom as found in nature; that is, the average of the masses of the known isotopes, weighted by their natural abundance. Physicists, on the other hand, defined it as 116 of the mass of an atom of the isotope oxygen-16 (16O).[13]

Definition by the IUPAC

The existence of two distinct units with the same name was confusing, and the difference (about 1.000282 in relative terms) was large enough to affect high-precision measurements. Moreover, it was discovered that the isotopes of oxygen had different natural abundances in water and in air. For these and other reasons, in 1961 the International Union of Pure and Applied Chemistry (IUPAC), which had absorbed the ICAW, adopted a new definition of the atomic mass unit for use in both physics and chemistry; namely, 112 of the mass of a carbon-12 atom. This new value was intermediate between the two earlier definitions, but closer to the one used by chemists (who would be affected the most by the change).[12][13]

The new unit was named the "unified atomic mass unit" and given a new symbol "u", to replace the old "amu" that had been used for the oxygen-based units.[17] However, the old symbol "amu" has sometimes been used, after 1961, to refer to the new unit, particularly in lay and preparatory contexts.

With this new definition, the standard atomic weight of carbon is approximately 12.011 Da, and that of oxygen is approximately 15.999 Da. These values, generally used in chemistry, are based on averages of many samples from Earth's crust, its atmosphere, and organic materials.

Adoption by the BIPM

The IUPAC 1961 definition of the unified atomic mass unit, with that name and symbol "u", was adopted by the International Bureau for Weights and Measures (BIPM) in 1971 as a non-SI unit accepted for use with the SI.[18]

Unit name

In 1993, the IUPAC proposed the shorter name "dalton" (with symbol "Da") for the unified atomic mass unit.[19][20] As with other unit names such as watt and newton, "dalton" is not capitalized in English, but its symbol, "Da", is capitalized. The name was endorsed by the International Union of Pure and Applied Physics (IUPAP) in 2005.[21]

In 2003 the name was recommended to the BIPM by the Consultative Committee for Units, part of the CIPM, as it "is shorter and works better with [the SI] prefixes".[22] In 2006, the BIPM included the dalton in its 8th edition of the formal definition of SI.[23] The name was also listed as an alternative to "unified atomic mass unit" by the International Organization for Standardization in 2009.[24][25] It is now recommended by several scientific publishers,[26] and some of them consider "atomic mass unit" and "amu" deprecated.[27] In 2019, the BIPM retained the dalton in its 9th edition of the formal definition of SI while dropping the unified atomic mass unit from its table of non-SI units accepted for use with the SI, but secondarily notes that the dalton (Da) and the unified atomic mass unit (u) are alternative names (and symbols) for the same unit.[1]

2019 redefinition of the SI base units

The definition of the dalton was not affected by the 2019 redefinition of SI base units,[28][29][1] that is, 1 Da in the SI is still 112 of the mass of a carbon-12 atom, a quantity that must be determined experimentally in terms of SI units. However, the definition of a mole was changed to be the amount of substance consisting of exactly 6.02214076×1023 entities and the definition of the kilogram was changed as well. As a consequence, the molar mass constant is no longer exactly 1 g/mol, meaning that the number of grams in the mass of one mole of any substance is no longer exactly equal to the number of daltons in its average molecular mass.[30]

Measurement

Although relative atomic masses are defined for neutral atoms, they are measured (by mass spectrometry) for ions: hence, the measured values must be corrected for the mass of the electrons that were removed to form the ions, and also for the mass equivalent of the electron binding energy, Eb/muc2. The total binding energy of the six electrons in a carbon-12 atom is 1030.1089 eV = 1.6504163×10−16 J: Eb/muc2 = 1.1058674×10−6, or about one part in 10 million of the mass of the atom.[31]

Before the 2019 redefinition of SI units, experiments were aimed to determine the value of the Avogadro constant for finding the value of the unified atomic mass unit.

Josef Loschmidt

 
Josef Loschmidt

A reasonably accurate value of the atomic mass unit was first obtained indirectly by Josef Loschmidt in 1865, by estimating the number of particles in a given volume of gas.[32]

Jean Perrin

Perrin estimated the Avogadro number by a variety of methods, at the turn of the 20th century. He was awarded the 1926 Nobel Prize in Physics, largely for this work.[33]

Coulometry

Main article: Coulometry

The electric charge per mole of elementary charges is a constant called the Faraday constant, F, whose value had been essentially known since 1834 when Michael Faraday published his works on electrolysis. In 1910, Robert Millikan obtained the first measurement of the charge on an electron, −e. The quotient F/e provided an estimate of the Avogadro constant.[34]

The classic experiment is that of Bower and Davis at NIST,[35] 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:

 

The NIST scientists devised a method to compensate for silver lost from the anode by mechanical causes, and conducted an isotope analysis of the silver used to determine its atomic weight. Their value for the conventional Faraday constant was F90 = 96485.39(13) C/mol, which corresponds to a value for the Avogadro constant of 6.0221449(78)×1023 mol−1: both values have a relative standard uncertainty of 1.3×10−6.

Electron mass measurement

In practice, the atomic mass constant is determined from the electron rest mass me and the electron relative atomic mass Ar(e) (that is, the mass of electron divided by the atomic mass constant).[36] The relative atomic mass of the electron can be measured in cyclotron experiments, while the rest mass of the electron can be derived from other physical constants.

 
 
 

where c is the speed of light, h is the Planck constant, α is the fine-structure constant, and R is the Rydberg constant.

As may be observed from the old values (2014 CODATA) in the table below, the main limiting factor in the precision of the Avogadro constant was the uncertainty in the value of the Planck constant, as all the other constants that contribute to the calculation were known more precisely.

Constant Symbol 2014 CODATA values Relative standard uncertainty Correlation coefficient with NA
Proton–electron mass ratio mp/me 1836.15267389(17) 9.5×10−11 −0.0003
Molar mass constant Mu 0.001 kg/mol = 1 g/mol 0 (defined)  —
Rydberg constant R 10973731.568508(65) m−1 5.9×10−12 −0.0002
Planck constant h 6.626070040(81)×10−34 J⋅s 1.2×10−8 −0.9993
Speed of light c 299792458 m/s 0 (defined)  —
Fine structure constant α 7.2973525664(17)×10−3 2.3×10−10 0.0193
Avogadro constant NA 6.022140857(74)×1023 mol−1 1.2×10−8 1

The power of the presently defined values of universal constants can be understood from the table below (2018 CODATA).

Constant Symbol 2018 CODATA values[37] Relative standard uncertainty Correlation coefficient with NA
Proton–electron mass ratio mp/me 1836.15267343(11) 6.0×10−11  —
Molar mass constant Mu 0.99999999965(30)×10−3 kg/mol 3.0×10−10  —
Rydberg constant R 10973731.568160(21) m−1 1.9×10−12  —
Planck constant h 6.62607015×10−34 J⋅s 0 (defined)  —
Speed of light c 299792458 m/s 0 (defined)  —
Fine structure constant α 7.2973525693(11)×10−3 1.5×10−10  —
Avogadro constant NA 6.02214076×1023 mol−1 0 (defined)  —

X-ray crystal density methods

 
Ball-and-stick model of the unit cell of silicon. X-ray diffraction measures the cell parameter, a, which is used to calculate a value for the Avogadro constant.

Silicon single crystals may be produced today in commercial facilities with extremely high purity and with few lattice defects. This method defined the Avogadro constant as the ratio of the molar volume, Vm, to the atomic volume Vatom:

 

where   and n is the number of atoms per unit cell of volume Vcell.

The unit cell of silicon has a cubic packing arrangement of 8 atoms, and the unit cell volume may be measured by determining a single unit cell parameter, the length a of one of the sides of the cube.[38] The 2018 CODATA value of a for silicon is 5.431020511(89)×10−10 m.[39]

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 isotope proportional composition of the sample used must be measured and taken into account. Silicon occurs in 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 standard atomic weights 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 determined:

 

where Mu is the molar mass constant. The 2018 CODATA value for the molar volume of silicon is 1.205883199(60)×10−5 m3⋅mol−1, with a relative standard uncertainty of 4.9×10−8.[40]

See also

Notes

  1. ^ The digits in parentheses indicate the uncertainty; see Uncertainty notation.

References

  1. ^ a b c d Bureau International des Poids et Mesures (2019): The International System of Units (SI), 9th edition, English version, page 146. Available at the BIPM website.
  2. ^ IUPAC, Compendium of Chemical Terminology, 2nd ed. (the "Gold Book") (1997). Online corrected version: (2006–) "atomic mass constant". doi:10.1351/goldbook.A00497
  3. ^ Barry N Taylor (2009). "Molar mass and related quantities in the New SI". Metrologia. 46 (3): L16–L19. doi:10.1088/0026-1394/46/3/L01. S2CID 115540416.
  4. ^ a b Berg, Jeremy M.; Tymoczko, John L.; Stryer, Lubert (2007). "2". Biochemistry (6th ed.). p. 35. ISBN 978-0-7167-8724-2.
  5. ^ Opitz CA, Kulke M, Leake MC, Neagoe C, Hinssen H, Hajjar RJ, Linke WA (October 2003). "Damped elastic recoil of the titin spring in myofibrils of human myocardium". Proc. Natl. Acad. Sci. U.S.A. 100 (22): 12688–93. Bibcode:2003PNAS..10012688O. doi:10.1073/pnas.2133733100. PMC 240679. PMID 14563922.
  6. ^ Integrated DNA Technologies (2011): "Molecular Facts and Figures 2020-04-18 at the Wayback Machine". Article on the IDT website, Support & Education section 2021-01-19 at the Wayback Machine, accessed on 2019-07-08.
  7. ^ "2018 CODATA Value: proton mass in u". The NIST Reference on Constants, Units, and Uncertainty. NIST. 20 May 2019. Retrieved 2022-09-11.
  8. ^ "2018 CODATA Value: neutron mass in u". The NIST Reference on Constants, Units, and Uncertainty. NIST. 20 May 2019. Retrieved 2020-06-24.
  9. ^ Meng Wang, G. Audi, F.G. Kondev, W.J. Huang, S. Naimi, and Xing Xu (2017): "The Ame2016 atomic mass evaluation (II). Tables, graphs and references". Chinese Physics C, volume 41, issue 3, article 030003, pages 1-441. doi:10.1088/1674-1137/41/3/030003
  10. ^ "2018 CODATA Value: atomic mass constant energy equivalent". The NIST Reference on Constants, Units, and Uncertainty. NIST. 20 May 2019. Retrieved 2019-07-21.
  11. ^ "2018 CODATA Value: atomic mass constant energy equivalent in MeV". The NIST Reference on Constants, Units, and Uncertainty. NIST. 20 May 2019. Retrieved 2019-07-21.
  12. ^ a b c Petley, B. W. (1989). "The atomic mass unit". IEEE Trans. Instrum. Meas. 38 (2): 175–179. doi:10.1109/19.192268.
  13. ^ a b c Holden, Norman E. (2004). "Atomic Weights and the International Committee—A Historical Review". Chemistry International. 26 (1): 4–7.
  14. ^ 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.
  15. ^ Chang, Raymond (2005). Physical Chemistry for the Biosciences. p. 5. ISBN 978-1-891389-33-7.
  16. ^ Kelter, Paul B.; Mosher, Michael D.; Scott, Andrew (2008). Chemistry: The Practical Science. Vol. 10. p. 60. ISBN 978-0-547-05393-6.
  17. ^ IUPAC, Compendium of Chemical Terminology, 2nd ed. (the "Gold Book") (1997). Online corrected version: (2006–) "unified atomic mass unit". doi:10.1351/goldbook.U06554
  18. ^ Bureau International des Poids et Mesures (1971): 14th Conference Générale des Poids et Mesures 2020-09-23 at the Wayback Machine Available at the BIPM website.
  19. ^ Mills, Ian; Cvitaš, Tomislav; Homann, Klaus; Kallay, Nikola; Kuchitsu, Kozo (1993). Quantities, Units and Symbols in Physical Chemistry International Union of Pure and Applied Chemistry; Physical Chemistry Division (2nd ed.). International Union of Pure and Applied Chemistry and published for them by Blackwell Science Ltd. ISBN 978-0-632-03583-0.
  20. ^ IUPAC, Compendium of Chemical Terminology, 2nd ed. (the "Gold Book") (1997). Online corrected version: (2006–) "dalton". doi:10.1351/goldbook.D01514
  21. ^ "IUPAP: C2: Report 2005". Retrieved 2018-07-15.
  22. ^ "Consultative Committee for Units (CCU); Report of the 15th meeting (17–18 April 2003) to the International Committee for Weights and Measures" (PDF). Retrieved 14 Aug 2010.
  23. ^ International Bureau of Weights and Measures (2006), The International System of Units (SI) (PDF) (8th ed.), pp. 114–15, ISBN 92-822-2213-6, (PDF) from the original on 2021-06-04, retrieved 2021-12-16
  24. ^ International Standard ISO 80000-1:2009 – Quantities and Units – Part 1: General. International Organization for Standardization. 2009.
  25. ^ International Standard ISO 80000-10:2009 – Quantities and units – Part 10: Atomic and nuclear physics, International Organization for Standardization, 2009
  26. ^ . AoB Plants. Oxford journals; Oxford University Press. Archived from the original on 2011-11-03. Retrieved 2010-08-22.
  27. ^ "Author guidelines". Rapid Communications in Mass Spectrometry. Wiley-Blackwell. 2010.
  28. ^ International Bureau for Weights and Measures (2017): Proceedings of the 106th meeting of the International Committee for Weights and Measures (CIPM), 16-17 and 20 October 2017, page 23. Available at the BIPM website 2021-02-21 at the Wayback Machine.
  29. ^ International Bureau for Weights and Measures (2018): Resolutions Adopted - 26th Conference Générale des Poids et Mesures 2018-11-19 at the Wayback Machine. Available at the BIPM website.
  30. ^ Lehmann, H. P.; Fuentes-Arderiu, X.; Bertello, L. F. (2016-02-29). "Unified Atomic Mass Unit". doi:10.1515/iupac.68.2930. {{cite journal}}: Cite journal requires |journal= (help)
  31. ^ Mohr, Peter J.; Taylor, Barry N. (2005). (PDF). Reviews of Modern Physics. 77 (1): 1–107. Bibcode:2005RvMP...77....1M. doi:10.1103/RevModPhys.77.1. Archived from the original (PDF) on 2017-10-01.
  32. ^ Loschmidt, J. (1865). "Zur Grösse der Luftmoleküle". Sitzungsberichte der Kaiserlichen Akademie der Wissenschaften Wien. 52 (2): 395–413. .
  33. ^ Oseen, C.W. (December 10, 1926). Presentation Speech for the 1926 Nobel Prize in Physics.
  34. ^ (1974): Introduction to the constants for nonexperts, 1900–1920 From the Encyclopaedia Britannica, 15th edition; reproduced by NIST. Accessed on 2019-07-03.
  35. ^ This account is based on the review in Mohr, Peter J.; Taylor, Barry N. (1999). (PDF). Journal of Physical and Chemical Reference Data. 28 (6): 1713–1852. Bibcode:1999JPCRD..28.1713M. doi:10.1063/1.556049. Archived from the original (PDF) on 2017-10-01.
  36. ^ Mohr, Peter J.; Taylor, Barry N. (1999). (PDF). Journal of Physical and Chemical Reference Data. 28 (6): 1713–1852. Bibcode:1999JPCRD..28.1713M. doi:10.1063/1.556049. Archived from the original (PDF) on 2017-10-01.
  37. ^ "Constants bibliography, source of the CODATA internationally recommended values". The NIST Reference on Constants, Units, and Uncertainty. Retrieved 4 August 2021.
  38. ^ "Unit Cell Formula". Mineralogy Database. 2000–2005. Retrieved 2007-12-09.
  39. ^ "2018 CODATA Value: lattice parameter of silicon". The NIST Reference on Constants, Units, and Uncertainty. NIST. 20 May 2019. Retrieved 2019-08-23.
  40. ^ "2018 CODATA Value: molar volume of silicon". The NIST Reference on Constants, Units, and Uncertainty. NIST. 20 May 2019. Retrieved 2019-08-23.

External links

  • Atomic weights and isotopic compositions
  • at sizes.com

May 18, 2023
dalton, unit, confused, with, hartree, atomic, units, dalton, unified, atomic, mass, unit, symbols, unit, mass, widely, used, physics, chemistry, defined, mass, unbound, neutral, atom, carbon, nuclear, electronic, ground, state, rest, atomic, mass, constant, d. Not to be confused with Hartree atomic units The dalton or unified atomic mass unit symbols Da or u is a non SI unit of mass widely used in physics and chemistry It is defined as 1 12 of the mass of an unbound neutral atom of carbon 12 in its nuclear and electronic ground state and at rest 1 2 The atomic mass constant denoted mu is defined identically giving mu m 12C 12 1 Da 3 dalton unified atomic mass unit Unit ofmassSymbolDa or uNamed afterJohn DaltonConversions1 Da or u in is equal to kg 1 660539 066 60 50 10 27 mu 1 me 1822 888486 209 53 MeV c2 931 494102 42 28 This unit is commonly used in physics and chemistry to express the mass of atomic scale objects such as atoms molecules and elementary particles both for discrete instances and multiple types of ensemble averages For example an atom of helium 4 has a mass of 4 0026 Da This is an intrinsic property of the isotope and all helium 4 atoms have the same mass Acetylsalicylic acid aspirin C9 H8 O4 has an average mass of approximately 180 157 Da However there are no acetylsalicylic acid molecules with this mass The two most common masses of individual acetylsalicylic acid molecules are 180 0423 Da having the most common isotopes and 181 0456 Da in which one carbon is carbon 13 The molecular masses of proteins nucleic acids and other large polymers are often expressed with the units kilodaltons kDa megadaltons MDa etc 4 Titin one of the largest known proteins has a molecular mass of between 3 and 3 7 megadaltons 5 The DNA of chromosome 1 in the human genome has about 249 million base pairs each with an average mass of about 650 Da or 156 GDa total 6 The mole is a unit of amount of substance widely used in chemistry and physics which was originally defined so that the mass of one mole of a substance measured in grams would be numerically equal to the average mass of one of its constituent particles measured in daltons That is the molar mass of a chemical compound was meant to be numerically equal to its average molecular mass For example the average mass of one molecule of water is about 18 0153 daltons and one mole of water is about 18 0153 grams A protein whose molecule has an average mass of 64 kDa would have a molar mass of 64 kg mol However while this equality can be assumed for almost all practical purposes it is now only approximate because of the way mole was redefined on 20 May 2019 4 1 In general the mass in daltons of an atom is numerically close but not exactly equal to the number of nucleons contained in its nucleus It follows that the molar mass of a compound grams per mole is numerically close to the average number of nucleons contained in each molecule By definition the mass of an atom of carbon 12 is 12 daltons which corresponds with the number of nucleons that it has 6 protons and 6 neutrons However the mass of an atomic scale object is affected by the binding energy of the nucleons in its atomic nuclei as well as the mass and binding energy of its electrons Therefore this equality holds only for the carbon 12 atom in the stated conditions and will vary for other substances For example the mass of one unbound atom of the common hydrogen isotope hydrogen 1 protium is 1 007825 032 241 94 Da a the mass of the proton is 1 007276 466 621 53 Da 7 the mass of one free neutron is 1 008664 915 95 49 Da 8 and the mass of one hydrogen 2 deuterium atom is 2 014101 778 114 122 Da 9 In general the difference absolute mass excess is less than 0 1 exceptions include hydrogen 1 about 0 8 helium 3 0 5 lithium 6 0 25 and beryllium 0 14 The dalton differs from the unit of mass in the atomic units systems which is the electron rest mass me Contents 1 Energy equivalents 2 History 2 1 Origin of the concept 2 2 Isotopic variation 2 3 Definition by the IUPAC 2 4 Adoption by the BIPM 2 5 Unit name 2 6 2019 redefinition of the SI base units 3 Measurement 3 1 Josef Loschmidt 3 2 Jean Perrin 3 3 Coulometry 3 4 Electron mass measurement 3 5 X ray crystal density methods 4 See also 5 Notes 6 References 7 External linksEnergy equivalents EditThe atomic mass constant can also be expressed as its energy equivalent muc2 The 2018 CODATA recommended values are muc2 1 492418 085 60 45 10 10 J 10 931 494102 42 28 MeV 11 The megaelectronvolt mass equivalent MeV c2 is commonly used as a unit of mass in particle physics and these values are also important for the practical determination of relative atomic masses History EditOrigin of the concept Edit Jean Perrin in 1926 The interpretation of the law of definite proportions in terms of the atomic theory of matter implied that the masses of atoms of various elements had definite ratios that depended on the elements While the actual masses were unknown the relative masses could be deduced from that law In 1803 John Dalton proposed to use the still unknown atomic mass of the lightest atom that of hydrogen as the natural unit of atomic mass This was the basis of the atomic weight scale 12 For technical reasons in 1898 chemist Wilhelm Ostwald and others proposed to redefine the unit of atomic mass as 1 16 of the mass of an oxygen atom 13 That proposal was formally adopted by the International Committee on Atomic Weights ICAW in 1903 That was approximately the mass of one hydrogen atom but oxygen was more amenable to experimental determination This suggestion was made before the discovery of the existence of elemental isotopes which occurred in 1912 12 The physicist Jean Perrin had adopted the same definition in 1909 during his experiments to determine the atomic masses and the Avogadro constant 14 This definition remained unchanged until 1961 15 16 Perrin also defined the mole as an amount of a compound that contained as many molecules as 32 grams of oxygen O2 He called that number the Avogadro number in honor of physicist Amedeo Avogadro Isotopic variation Edit The discovery of isotopes of oxygen in 1929 required a more precise definition of the unit Unfortunately two distinct definitions came into use Chemists choose to define the AMU as 1 16 of the average mass of an oxygen atom as found in nature that is the average of the masses of the known isotopes weighted by their natural abundance Physicists on the other hand defined it as 1 16 of the mass of an atom of the isotope oxygen 16 16O 13 Definition by the IUPAC Edit The existence of two distinct units with the same name was confusing and the difference about 1 000282 in relative terms was large enough to affect high precision measurements Moreover it was discovered that the isotopes of oxygen had different natural abundances in water and in air For these and other reasons in 1961 the International Union of Pure and Applied Chemistry IUPAC which had absorbed the ICAW adopted a new definition of the atomic mass unit for use in both physics and chemistry namely 1 12 of the mass of a carbon 12 atom This new value was intermediate between the two earlier definitions but closer to the one used by chemists who would be affected the most by the change 12 13 The new unit was named the unified atomic mass unit and given a new symbol u to replace the old amu that had been used for the oxygen based units 17 However the old symbol amu has sometimes been used after 1961 to refer to the new unit particularly in lay and preparatory contexts With this new definition the standard atomic weight of carbon is approximately 12 011 Da and that of oxygen is approximately 15 999 Da These values generally used in chemistry are based on averages of many samples from Earth s crust its atmosphere and organic materials Adoption by the BIPM Edit The IUPAC 1961 definition of the unified atomic mass unit with that name and symbol u was adopted by the International Bureau for Weights and Measures BIPM in 1971 as a non SI unit accepted for use with the SI 18 Unit name Edit In 1993 the IUPAC proposed the shorter name dalton with symbol Da for the unified atomic mass unit 19 20 As with other unit names such as watt and newton dalton is not capitalized in English but its symbol Da is capitalized The name was endorsed by the International Union of Pure and Applied Physics IUPAP in 2005 21 In 2003 the name was recommended to the BIPM by the Consultative Committee for Units part of the CIPM as it is shorter and works better with the SI prefixes 22 In 2006 the BIPM included the dalton in its 8th edition of the formal definition of SI 23 The name was also listed as an alternative to unified atomic mass unit by the International Organization for Standardization in 2009 24 25 It is now recommended by several scientific publishers 26 and some of them consider atomic mass unit and amu deprecated 27 In 2019 the BIPM retained the dalton in its 9th edition of the formal definition of SI while dropping the unified atomic mass unit from its table of non SI units accepted for use with the SI but secondarily notes that the dalton Da and the unified atomic mass unit u are alternative names and symbols for the same unit 1 2019 redefinition of the SI base units Edit The definition of the dalton was not affected by the 2019 redefinition of SI base units 28 29 1 that is 1 Da in the SI is still 1 12 of the mass of a carbon 12 atom a quantity that must be determined experimentally in terms of SI units However the definition of a mole was changed to be the amount of substance consisting of exactly 6 022140 76 1023 entities and the definition of the kilogram was changed as well As a consequence the molar mass constant is no longer exactly 1 g mol meaning that the number of grams in the mass of one mole of any substance is no longer exactly equal to the number of daltons in its average molecular mass 30 Measurement EditAlthough relative atomic masses are defined for neutral atoms they are measured by mass spectrometry for ions hence the measured values must be corrected for the mass of the electrons that were removed to form the ions and also for the mass equivalent of the electron binding energy Eb muc2 The total binding energy of the six electrons in a carbon 12 atom is 1030 1089 eV 1 6504163 10 16 J Eb muc2 1 1058674 10 6 or about one part in 10 million of the mass of the atom 31 Before the 2019 redefinition of SI units experiments were aimed to determine the value of the Avogadro constant for finding the value of the unified atomic mass unit Josef Loschmidt Edit Josef Loschmidt A reasonably accurate value of the atomic mass unit was first obtained indirectly by Josef Loschmidt in 1865 by estimating the number of particles in a given volume of gas 32 Jean Perrin Edit Perrin estimated the Avogadro number by a variety of methods at the turn of the 20th century He was awarded the 1926 Nobel Prize in Physics largely for this work 33 Coulometry Edit Main article Coulometry The electric charge per mole of elementary charges is a constant called the Faraday constant F whose value had been essentially known since 1834 when Michael Faraday published his works on electrolysis In 1910 Robert Millikan obtained the first measurement of the charge on an electron e The quotient F e provided an estimate of the Avogadro constant 34 The classic experiment is that of Bower and Davis at NIST 35 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 A r M u I t m displaystyle F frac A rm r M rm u It m The NIST scientists devised a method to compensate for silver lost from the anode by mechanical causes and conducted an isotope analysis of the silver used to determine its atomic weight Their value for the conventional Faraday constant was F90 96485 39 13 C mol which corresponds to a value for the Avogadro constant of 6 0221449 78 1023 mol 1 both values have a relative standard uncertainty of 1 3 10 6 Electron mass measurement Edit In practice the atomic mass constant is determined from the electron rest mass me and the electron relative atomic mass Ar e that is the mass of electron divided by the atomic mass constant 36 The relative atomic mass of the electron can be measured in cyclotron experiments while the rest mass of the electron can be derived from other physical constants m u m e A r e 2 R h A r e c a 2 displaystyle m rm u frac m rm e A rm r rm e frac 2R infty h A rm r rm e c alpha 2 m u M u N A displaystyle m rm u frac M rm u N rm A N A M u A r e m e M u A r e c a 2 2 R h displaystyle N rm A frac M rm u A rm r rm e m rm e frac M rm u A rm r rm e c alpha 2 2R infty h where c is the speed of light h is the Planck constant a is the fine structure constant and R is the Rydberg constant As may be observed from the old values 2014 CODATA in the table below the main limiting factor in the precision of the Avogadro constant was the uncertainty in the value of the Planck constant as all the other constants that contribute to the calculation were known more precisely Constant Symbol 2014 CODATA values Relative standard uncertainty Correlation coefficient with NAProton electron mass ratio mp me 1836 152673 89 17 9 5 10 11 0 0003Molar mass constant Mu 0 001 kg mol 1 g mol 0 defined Rydberg constant R 10973 731 568508 65 m 1 5 9 10 12 0 0002Planck constant h 6 626070 040 81 10 34 J s 1 2 10 8 0 9993Speed of light c 299792 458 m s 0 defined Fine structure constant a 7 297352 5664 17 10 3 2 3 10 10 0 0193Avogadro constant NA 6 022140 857 74 1023 mol 1 1 2 10 8 1The power of the presently defined values of universal constants can be understood from the table below 2018 CODATA Constant Symbol 2018 CODATA values 37 Relative standard uncertainty Correlation coefficient with NAProton electron mass ratio mp me 1836 152673 43 11 6 0 10 11 Molar mass constant Mu 0 999999 999 65 30 10 3 kg mol 3 0 10 10 Rydberg constant R 10973 731 568160 21 m 1 1 9 10 12 Planck constant h 6 626070 15 10 34 J s 0 defined Speed of light c 299792 458 m s 0 defined Fine structure constant a 7 297352 5693 11 10 3 1 5 10 10 Avogadro constant NA 6 022140 76 1023 mol 1 0 defined X ray crystal density methods Edit Ball and stick model of the unit cell of silicon X ray diffraction measures the cell parameter a which is used to calculate a value for the Avogadro constant Silicon single crystals may be produced today in commercial facilities with extremely high purity and with few lattice defects This method defined the Avogadro constant as the ratio of the molar volume Vm to the atomic volume Vatom N A V m V a t o m displaystyle N rm A frac V rm m V rm atom where V a t o m V c e l l n displaystyle V rm atom frac V rm cell n and n is the number of atoms per unit cell of volume Vcell The unit cell of silicon has a cubic packing arrangement of 8 atoms and the unit cell volume may be measured by determining a single unit cell parameter the length a of one of the sides of the cube 38 The 2018 CODATA value of a for silicon is 5 431020 511 89 10 10 m 39 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 isotope proportional composition of the sample used must be measured and taken into account Silicon occurs in 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 standard atomic weights of the three nuclides are known with great accuracy This together with the measured density r of the sample allows the molar volume Vm to be determined V m A r M u r displaystyle V rm m frac A rm r M rm u rho where Mu is the molar mass constant The 2018 CODATA value for the molar volume of silicon is 1 205883 199 60 10 5 m3 mol 1 with a relative standard uncertainty of 4 9 10 8 40 See also Edit Physics portalMass mass spectrometry Kendrick mass Monoisotopic mass Mass to charge ratioNotes Edit The digits in parentheses indicate the uncertainty see Uncertainty notation References Edit a b c d Bureau International des Poids et Mesures 2019 The International System of Units SI 9th edition English version page 146 Available at the BIPM website IUPAC Compendium of Chemical Terminology 2nd ed the Gold Book 1997 Online corrected version 2006 atomic mass constant doi 10 1351 goldbook A00497 Barry N Taylor 2009 Molar mass and related quantities in the New SI Metrologia 46 3 L16 L19 doi 10 1088 0026 1394 46 3 L01 S2CID 115540416 a b Berg Jeremy M Tymoczko John L Stryer Lubert 2007 2 Biochemistry 6th ed p 35 ISBN 978 0 7167 8724 2 Opitz CA Kulke M Leake MC Neagoe C Hinssen H Hajjar RJ Linke WA October 2003 Damped elastic recoil of the titin spring in myofibrils of human myocardium Proc Natl Acad Sci U S A 100 22 12688 93 Bibcode 2003PNAS 10012688O doi 10 1073 pnas 2133733100 PMC 240679 PMID 14563922 Integrated DNA Technologies 2011 Molecular Facts and Figures Archived 2020 04 18 at the Wayback Machine Article on the IDT website Support amp Education section Archived 2021 01 19 at the Wayback Machine accessed on 2019 07 08 2018 CODATA Value proton mass in u The NIST Reference on Constants Units and Uncertainty NIST 20 May 2019 Retrieved 2022 09 11 2018 CODATA Value neutron mass in u The NIST Reference on Constants Units and Uncertainty NIST 20 May 2019 Retrieved 2020 06 24 Meng Wang G Audi F G Kondev W J Huang S Naimi and Xing Xu 2017 The Ame2016 atomic mass evaluation II Tables graphs and references Chinese Physics C volume 41 issue 3 article 030003 pages 1 441 doi 10 1088 1674 1137 41 3 030003 2018 CODATA Value atomic mass constant energy equivalent The NIST Reference on Constants Units and Uncertainty NIST 20 May 2019 Retrieved 2019 07 21 2018 CODATA Value atomic mass constant energy equivalent in MeV The NIST Reference on Constants Units and Uncertainty NIST 20 May 2019 Retrieved 2019 07 21 a b c Petley B W 1989 The atomic mass unit IEEE Trans Instrum Meas 38 2 175 179 doi 10 1109 19 192268 a b c Holden Norman E 2004 Atomic Weights and the International Committee A Historical Review Chemistry International 26 1 4 7 Perrin Jean 1909 Mouvement brownien et realite moleculaire Annales de Chimie et de Physique 8e Serie 18 1 114 Extract in English translation by Frederick Soddy Chang Raymond 2005 Physical Chemistry for the Biosciences p 5 ISBN 978 1 891389 33 7 Kelter Paul B Mosher Michael D Scott Andrew 2008 Chemistry The Practical Science Vol 10 p 60 ISBN 978 0 547 05393 6 IUPAC Compendium of Chemical Terminology 2nd ed the Gold Book 1997 Online corrected version 2006 unified atomic mass unit doi 10 1351 goldbook U06554 Bureau International des Poids et Mesures 1971 14th Conference Generale des Poids et Mesures Archived 2020 09 23 at the Wayback Machine Available at the BIPM website Mills Ian Cvitas Tomislav Homann Klaus Kallay Nikola Kuchitsu Kozo 1993 Quantities Units and Symbols in Physical Chemistry International Union of Pure and Applied Chemistry Physical Chemistry Division 2nd ed International Union of Pure and Applied Chemistry and published for them by Blackwell Science Ltd ISBN 978 0 632 03583 0 IUPAC Compendium of Chemical Terminology 2nd ed the Gold Book 1997 Online corrected version 2006 dalton doi 10 1351 goldbook D01514 IUPAP C2 Report 2005 Retrieved 2018 07 15 Consultative Committee for Units CCU Report of the 15th meeting 17 18 April 2003 to the International Committee for Weights and Measures PDF Retrieved 14 Aug 2010 International Bureau of Weights and Measures 2006 The International System of Units SI PDF 8th ed pp 114 15 ISBN 92 822 2213 6 archived PDF from the original on 2021 06 04 retrieved 2021 12 16 International Standard ISO 80000 1 2009 Quantities and Units Part 1 General International Organization for Standardization 2009 International Standard ISO 80000 10 2009 Quantities and units Part 10 Atomic and nuclear physics International Organization for Standardization 2009 Instructions to Authors AoB Plants Oxford journals Oxford University Press Archived from the original on 2011 11 03 Retrieved 2010 08 22 Author guidelines Rapid Communications in Mass Spectrometry Wiley Blackwell 2010 International Bureau for Weights and Measures 2017 Proceedings of the 106th meeting of the International Committee for Weights and Measures CIPM 16 17 and 20 October 2017 page 23 Available at the BIPM website Archived 2021 02 21 at the Wayback Machine International Bureau for Weights and Measures 2018 Resolutions Adopted 26th Conference Generale des Poids et Mesures Archived 2018 11 19 at the Wayback Machine Available at the BIPM website Lehmann H P Fuentes Arderiu X Bertello L F 2016 02 29 Unified Atomic Mass Unit doi 10 1515 iupac 68 2930 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Mohr Peter J Taylor Barry N 2005 CODATA recommended values of the fundamental physical constants 2002 PDF Reviews of Modern Physics 77 1 1 107 Bibcode 2005RvMP 77 1M doi 10 1103 RevModPhys 77 1 Archived from the original PDF on 2017 10 01 Loschmidt J 1865 Zur Grosse der Luftmolekule Sitzungsberichte der Kaiserlichen Akademie der Wissenschaften Wien 52 2 395 413 English translation Oseen C W December 10 1926 Presentation Speech for the 1926 Nobel Prize in Physics 1974 Introduction to the constants for nonexperts 1900 1920 From the Encyclopaedia Britannica 15th edition reproduced by NIST Accessed on 2019 07 03 This account is based on the review in Mohr Peter J Taylor Barry N 1999 CODATA recommended values of the fundamental physical constants 1998 PDF Journal of Physical and Chemical Reference Data 28 6 1713 1852 Bibcode 1999JPCRD 28 1713M doi 10 1063 1 556049 Archived from the original PDF on 2017 10 01 Mohr Peter J Taylor Barry N 1999 CODATA recommended values of the fundamental physical constants 1998 PDF Journal of Physical and Chemical Reference Data 28 6 1713 1852 Bibcode 1999JPCRD 28 1713M doi 10 1063 1 556049 Archived from the original PDF on 2017 10 01 Constants bibliography source of the CODATA internationally recommended values The NIST Reference on Constants Units and Uncertainty Retrieved 4 August 2021 Unit Cell Formula Mineralogy Database 2000 2005 Retrieved 2007 12 09 2018 CODATA Value lattice parameter of silicon The NIST Reference on Constants Units and Uncertainty NIST 20 May 2019 Retrieved 2019 08 23 2018 CODATA Value molar volume of silicon The NIST Reference on Constants Units and Uncertainty NIST 20 May 2019 Retrieved 2019 08 23 External links EditAtomic weights and isotopic compositions atomic mass unit at sizes com Retrieved from https en wikipedia org w index php title Dalton unit amp oldid 1152339204, wikipedia, wiki, book, books, library,

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