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{{Nuclear physics|expanded=Nuclides' classification}} | |||
The '''mass number''' (symbol ''A'', from the German word ''Atomgewicht'' (atomic weight),<ref>Jensen, William B. (2005). The Origins of the Symbols A and Z for Atomic Weight and Number. ''J. Chem. Educ.'' 82: 1764. .</ref> also called '''atomic mass number''' or '''nucleon number''', is the total number of ]s and ]s (together known as ]s) in an ]. It |
The '''mass number''' (symbol ''A'', from the German word ''Atomgewicht'' (atomic weight),<ref>Jensen, William B. (2005). The Origins of the Symbols A and Z for Atomic Weight and Number. ''J. Chem. Educ.'' 82: 1764. .</ref> also called '''atomic mass number''' or '''nucleon number''', is the total number of ]s and ]s (together known as ]s) in an ]. It is approximately equal to the ] of the ] expressed in ]s. Because protons and neutrons both are ]s, the mass number ''A'' is identical with the ] B as of the nucleus as of the whole atom or ]. The mass number is different for each different ] of a ]. Hence, the difference between the mass number and the ] ''Z'' gives the ] (''N'') in a given nucleus: {{tmath|1=N=A-Z}}.<ref>{{cite web|url=http://education.jlab.org/qa/pen_number.html|title=How many protons, electrons and neutrons are in an atom of krypton, carbon, oxygen, neon, silver, gold, etc...?|publisher=Thomas Jefferson National Accelerator Facility|accessdate=2008-08-27}}</ref> | ||
The mass number is written either after the element name or as a ] to the left of an element's symbol. For example, the most common isotope of ] is ], or {{SimpleNuclide2|carbon|12}}, which has 6 protons and 6 neutrons. The full isotope symbol would also have the atomic number (''Z'') as a subscript to the left of the element symbol directly below the mass number: {{nuclide|carbon|12}}.<ref>{{cite web|url=http://www.fordhamprep.org/gcurran/sho/sho/lessons/lesson35.htm|title=Elemental Notation and Isotopes|publisher=Science Help Online|accessdate=2008-08-27|deadurl=yes|archiveurl=https://web.archive.org/web/20080913063710/http://www.fordhamprep.org/gcurran/sho/sho/lessons/lesson35.htm|archivedate=2008-09-13|df=}}</ref> This is technically redundant, as each element is defined by its atomic number, so it is often omitted. | The mass number is written either after the element name or as a ] to the left of an element's symbol. For example, the most common isotope of ] is ], or {{SimpleNuclide2|carbon|12}}, which has 6 protons and 6 neutrons. The full isotope symbol would also have the atomic number (''Z'') as a subscript to the left of the element symbol directly below the mass number: {{nuclide|carbon|12}}.<ref>{{cite web|url=http://www.fordhamprep.org/gcurran/sho/sho/lessons/lesson35.htm|title=Elemental Notation and Isotopes|publisher=Science Help Online|accessdate=2008-08-27|deadurl=yes|archiveurl=https://web.archive.org/web/20080913063710/http://www.fordhamprep.org/gcurran/sho/sho/lessons/lesson35.htm|archivedate=2008-09-13|df=}}</ref> This is technically redundant, as each element is defined by its atomic number, so it is often omitted. | ||
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On the other hand, ] naturally decays by radioactive ], whereby one neutron is transmuted into a proton with the emission of an ] and an ]. Thus the atomic number increases by 1 (''Z'': 6→7) and the mass number remains the same (''A'' = 14), while the number of neutrons decreases by 1 (''N'': 8→7).<ref>{{cite book | On the other hand, ] naturally decays by radioactive ], whereby one neutron is transmuted into a proton with the emission of an ] and an ]. Thus the atomic number increases by 1 (''Z'': 6→7) and the mass number remains the same (''A'' = 14), while the number of neutrons decreases by 1 (''N'': 8→7).<ref>{{cite book | ||
| last = Curran | | last = Curran | ||
| first = Greg | | first = Greg | ||
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|{{nuclide|carbon|14}} ||→ ||{{nuclide|nitrogen|14}} ||+ ||{{SubatomicParticle|Electron}} ||+ ||{{SubatomicParticle|Electron Antineutrino}} | |{{nuclide|carbon|14}} ||→ ||{{nuclide|nitrogen|14}} ||+ ||{{SubatomicParticle|Electron}} ||+ ||{{SubatomicParticle|Electron Antineutrino}} | ||
|} | |} | ||
Beta decay is only possible because ''A'' doesn't ''determine'' atomic mass. Indeed, masses of different ]—atoms having the same mass number—have differences on order of few ]es. | |||
Another type of radioactive decay without change in mass number is emission of a ] from a ] or ] excited state of an atomic nucleus. Since all the protons and neutrons remain in the nucleus unchanged in this process, the mass number is also unchanged. | Another type of radioactive decay without change in mass number is emission of a ] from a ] or ] excited state of an atomic nucleus. Since all the protons and neutrons remain in the nucleus unchanged in this process, the mass number is also unchanged. | ||
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There are two reasons for ]/]: | There are two reasons for ]/]: | ||
# The neutron is slightly heavier than the proton. This increases the mass of nuclei with more neutrons than protons relative to the atomic mass unit scale based on <sup>12</sup>C with equal numbers of protons and neutrons. | # The neutron is slightly heavier than the proton. This increases the mass of nuclei with more neutrons than protons relative to the atomic mass unit scale based on <sup>12</sup>C with equal numbers of protons and neutrons. | ||
# The nuclear ] varies between nuclei. A nucleus with greater binding energy has a lower total energy, and therefore a lower mass according to Einstein's ] relation ''E'' = ''mc''<sup>2</sup>. For <sup>35</sup>Cl the isotopic mass is less than 35 so this must be the dominant factor. | # The nuclear ] varies between nuclei. A nucleus with greater binding energy has a lower total energy, and therefore a lower mass according to Einstein's ] relation ''E'' = ''mc''<sup>2</sup>. For <sup>35</sup>Cl the isotopic mass is less than 35 so this must be the dominant factor. | ||
==Relative atomic mass of an element== | ==Relative atomic mass of an element== |
Revision as of 16:50, 30 August 2019
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The mass number (symbol A, from the German word Atomgewicht (atomic weight), also called atomic mass number or nucleon number, is the total number of protons and neutrons (together known as nucleons) in an atomic nucleus. It is approximately equal to the atomic (also known as isotopic) mass of the atom expressed in atomic mass units. Because protons and neutrons both are baryons, the mass number A is identical with the baryon number B as of the nucleus as of the whole atom or ion. The mass number is different for each different isotope of a chemical element. Hence, the difference between the mass number and the atomic number Z gives the number of neutrons (N) in a given nucleus: .
The mass number is written either after the element name or as a superscript to the left of an element's symbol. For example, the most common isotope of carbon is carbon-12, or
C
, which has 6 protons and 6 neutrons. The full isotope symbol would also have the atomic number (Z) as a subscript to the left of the element symbol directly below the mass number:
6C
. This is technically redundant, as each element is defined by its atomic number, so it is often omitted.
Mass number changes in radioactive decay
Different types of radioactive decay are characterized by their changes in mass number as well as atomic number, according to the radioactive displacement law of Fajans and Soddy.
For example, uranium-238 usually decays by alpha decay, where the nucleus loses two neutrons and two protons in the form of an alpha particle. Thus the atomic number and the number of neutrons each decrease by 2 (Z: 92→90, N: 146→144), so that the mass number decreases by 4 (A = 238→234); the result is an atom of thorium-234 and an alpha particle (
2He
):
92U
→
90Th
+
2He
On the other hand, carbon-14 naturally decays by radioactive beta decay, whereby one neutron is transmuted into a proton with the emission of an electron and an antineutrino. Thus the atomic number increases by 1 (Z: 6→7) and the mass number remains the same (A = 14), while the number of neutrons decreases by 1 (N: 8→7). The resulting atom is nitrogen-14, with seven protons and seven neutrons:
6C
→
7N
+
e
+
ν
e
Beta decay is only possible because A doesn't determine atomic mass. Indeed, masses of different isobars—atoms having the same mass number—have differences on order of few electron masses.
Another type of radioactive decay without change in mass number is emission of a gamma ray from a nuclear isomer or metastable excited state of an atomic nucleus. Since all the protons and neutrons remain in the nucleus unchanged in this process, the mass number is also unchanged.
Mass number and isotopic mass
The mass number gives an estimate of the isotopic mass measured in atomic mass units (u). For C the isotopic mass is exactly 12, since the atomic mass unit is defined as 1/12 of the mass of C. For other isotopes, the isotopic mass is usually within 0.1 u of the mass number. For example, Cl (17 protons and 18 neutrons) has a mass number of 35 and an isotopic mass of 34.96885. The difference between mass number of an atom and its isotopic mass is known as the mass excess. Mass excess should not be confused with mass defect which is the difference between the mass of an atom and its constituent particles (namely protons, neutrons and electrons).
There are two reasons for mass defect/excess:
- The neutron is slightly heavier than the proton. This increases the mass of nuclei with more neutrons than protons relative to the atomic mass unit scale based on C with equal numbers of protons and neutrons.
- The nuclear binding energy varies between nuclei. A nucleus with greater binding energy has a lower total energy, and therefore a lower mass according to Einstein's mass–energy equivalence relation E = mc. For Cl the isotopic mass is less than 35 so this must be the dominant factor.
Relative atomic mass of an element
The mass number should also not be confused with the standard atomic weight (also called atomic weight) of an element, which is the ratio of the average atomic mass of the different isotopes of that element (weighted by abundance) to the unified atomic mass unit. The atomic weight is an actual mass (made relative, i.e., a ratio), while the mass number is a counted number (and so an integer).
This weighted average can be quite different from the near-integer values for individual isotopic masses. For instance, there are two main isotopes of chlorine: chlorine-35 and chlorine-37. In any given sample of chlorine that has not been subjected to mass separation there will be roughly 75% of chlorine atoms which are chlorine-35 and only 25% of chlorine atoms which are chlorine-37. This gives chlorine a relative atomic mass of 35.5 (actually 35.4527 g/mol).
Moreover, the weighted average mass can be near-integer, but at the same time not corresponding to the mass of any natural isotope. For example, bromine has only two stable isotopes, Br and Br, naturally present in approximately equal fractions, which leads to the standard atomic mass of bromine close to 80 (79.904 g/mol), even though the isotope Br with such mass is unstable.
References
- Jensen, William B. (2005). The Origins of the Symbols A and Z for Atomic Weight and Number. J. Chem. Educ. 82: 1764. link.
- "How many protons, electrons and neutrons are in an atom of krypton, carbon, oxygen, neon, silver, gold, etc...?". Thomas Jefferson National Accelerator Facility. Retrieved 2008-08-27.
- "Elemental Notation and Isotopes". Science Help Online. Archived from the original on 2008-09-13. Retrieved 2008-08-27.
{{cite web}}
: Unknown parameter|deadurl=
ignored (|url-status=
suggested) (help) - Suchocki, John. Conceptual Chemistry, 2007. Page 119.
- Curran, Greg (2004). Homework Helpers. Career Press. pp. 78–79. ISBN 1-56414-721-5.
- "IUPAC Definition of Relative Atomic Mass". International Union of Pure and Applied Chemistry. Retrieved 2008-08-27.
- "Atomic Weights and Isotopic Compositions for All Elements". NIST.
Further reading
- Bishop, Mark. "The Structure of Matter and Chemical Elements (ch. 3)". An Introduction to Chemistry. Chiral Publishing. p. 93. ISBN 978-0-9778105-4-3. Retrieved 2008-07-08.
{{cite book}}
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suggested) (help)