Chlorine-37: Difference between revisions
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{{Short description|Isotope of chlorine}} |
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{{Infobox isotope |
{{Infobox isotope |
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|background = #999999 |
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|isotope_name = Chlorine-37 |
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|num_neutrons = 20 |
|num_neutrons = 20 |
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|num_protons = 17 |
|num_protons = 17 |
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|isotope_filename = |
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|alternate_names = |
|alternate_names = |
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|mass_number=37 |
|mass_number=37 |
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|symbol=Cl |
|symbol=Cl |
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|decay_product = None |
|decay_product = None |
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|halflife= |
|halflife= |
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|error_halflife = |
|error_halflife = |
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|mass= |
|mass=36.965903 |
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|mass number=37 |
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|excess_energy = |
|excess_energy = |
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|error1 = |
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|binding_energy = |
|binding_energy = |
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|error2 = |
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|spin = |
|spin = |
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|decay_mode1= |
|decay_mode1= |
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}} |
}} |
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'''Chlorine-37''' |
'''Chlorine-37''' ({{SimpleNuclide|Chlorine|37}}), is one of the [[stable isotope]]s of [[chlorine]], the other being chlorine-35 ({{SimpleNuclide|Chlorine|35}}). Its [[atomic nucleus|nucleus]] contains 17 [[protons]] and 20 [[neutrons]] for a total of 37 [[nucleon]]s. Chlorine-37 accounts for 24.23% of natural chlorine, chlorine-35 accounting for 75.77%, giving chlorine [[atom]]s in bulk an apparent atomic weight of {{val|35.45|(1)|u=g/mol}}.<ref>{{Citation |last=Prohaska |first=Thomas |title=Standard atomic weights of the elements 2021 (IUPAC Technical Report) |date=2022-05-25 |work=Pure and Applied Chemistry |volume=94 |issue=5 |pages=573–600 |year=2022 |url=https://www.degruyter.com/document/doi/10.1515/pac-2019-0603/html |access-date=2024-06-07 |language=en |doi=10.1515/pac-2019-0603 |issn=0033-4545 |last2=Irrgeher |first2=Johanna |last3=Benefield |first3=Jacqueline |last4=Böhlke |first4=John K. |last5=Chesson |first5=Lesley A. |last6=Coplen |first6=Tyler B. |last7=Ding |first7=Tiping |last8=Dunn |first8=Philip J. H. |last9=Gröning |first9=Manfred |doi-access=free |display-authors=1}}</ref> |
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Remarkably, |
Remarkably, solar neutrinos were discovered by an experiment ([[Homestake Experiment]]) using a radiochemical method based on chlorine-37 transmutation.<ref name="SciAm"> |
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{{cite journal|doi=10.1038/scientificamerican0769-28|author=J.N. Bahcall|title=Neutrinos from the Sun|url=http://www.sns.ias.edu/~jnb/Papers/Popular/Scientificamerican69/scientificamerican69.html|journal = [[Scientific American]]|volume = 221 |issue = 1 |year = 1969|pages=28–37|bibcode=1969SciAm.221a..28B}}</ref> |
{{cite journal|doi=10.1038/scientificamerican0769-28|author=J.N. Bahcall|title=Neutrinos from the Sun|url=http://www.sns.ias.edu/~jnb/Papers/Popular/Scientificamerican69/scientificamerican69.html|journal = [[Scientific American]]|volume = 221 |issue = 1 |year = 1969|pages=28–37|bibcode=1969SciAm.221a..28B}}</ref> |
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One of the historically important radiochemical methods of solar [[Neutrino detector|neutrino detection]] is based on inverse [[electron capture]] triggered by the absorption of an [[electron neutrino]].<ref name="Sutton"> |
One of the historically important radiochemical methods of solar [[Neutrino detector|neutrino detection]] is based on inverse [[electron capture]] triggered by the absorption of an [[electron neutrino]].<ref name="Sutton"> |
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{{cite book|last=Sutton|first=Christine|title=Spaceship Neutrino|url=https:// |
{{cite book|last=Sutton|first=Christine|title=Spaceship Neutrino|url=https://archive.org/details/spaceshipneutrin0000sutt|url-access=registration|quote=chlorine-37 neutrino.|publisher=[[Cambridge University Press]]|pages=[https://archive.org/details/spaceshipneutrin0000sutt/page/151 151]–152|year=1992|isbn=978-0-521-36404-1|oclc=25246163}}</ref> Chlorine-37 transmutes into argon-37 via the reaction<ref> |
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{{cite book|author=F.H. Shu|title=The Physical Universe: An Introduction to Astronomy|url=https:// |
{{cite book|author=F.H. Shu|title=The Physical Universe: An Introduction to Astronomy|url=https://archive.org/details/physicaluniverse00shuf|url-access=registration|quote=chlorine 37 neutrino.|publisher=University Science Books|page=[https://archive.org/details/physicaluniverse00shuf/page/n145 122]|year=1982|isbn=978-0-935702-05-7}}</ref> |
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:{{SimpleNuclide|Chlorine|37}} + {{Subatomic particle|Electron neutrino}} → {{SimpleNuclide|Argon|37}} + {{Subatomic particle|Electron-}}. |
:{{SimpleNuclide|Chlorine|37}} + {{Subatomic particle|Electron neutrino}} → {{SimpleNuclide|Argon|37}} + {{Subatomic particle|Electron-}}. |
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Argon-37 then |
Argon-37 then decays via [[electron capture]] (half-life 35 d) into chlorine-37 via the reaction |
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:{{SimpleNuclide|Argon|37}} + {{Subatomic particle|Electron-}} → {{SimpleNuclide|Chlorine|37}} + {{Subatomic particle|Electron neutrino}}. |
:{{SimpleNuclide|Argon|37}} + {{Subatomic particle|Electron-}} → {{SimpleNuclide|Chlorine|37}} + {{Subatomic particle|Electron neutrino}}. |
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These last reactions involve [[Auger electron]]s of specific energies.<ref name="Sutton"/><ref> |
These last reactions involve [[Auger electron]]s of specific energies.<ref name="Sutton"/><ref> |
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{{cite journal|author=A.H. Snell, F. Pleasonton|title=Spectrometry of the Neutrino Recoils of Argon-37|journal=[[Physical Review]]|volume=100 |issue=5 |pages=1396–1403|year=1955|doi=10.1103/PhysRev.100.1396 |
{{cite journal|author=A.H. Snell, F. Pleasonton|title=Spectrometry of the Neutrino Recoils of Argon-37|journal=[[Physical Review]]|volume=100 |issue=5 |pages=1396–1403|year=1955|doi=10.1103/PhysRev.100.1396 |
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|bibcode = 1955PhRv..100.1396S}}</ref> The detection of these electrons confirms that a neutrino event |
|bibcode = 1955PhRv..100.1396S}}</ref> The detection of these electrons confirms that a neutrino event occurred. Detection methods involve several hundred thousand liters of [[carbon tetrachloride]] (CCl<sub>4</sub>) or [[tetrachloroethylene]]<!--Also known as perchloroethylene, perchloroethene, perc, PCE --> (C<sub>2</sub>Cl<sub>4</sub>) stored in underground tanks.<ref name="SciAm"/><ref name="Sutton"/><ref>{{cite book|author = A. Bhatnagar, W. Livingston|title = Fundamental of Solar Astronomy|url = https://books.google.com/books?id=fe7XDuxCYjcC&dq=chlorine+37+neutrino&pg=PA88|publisher=[[World Scientific]]|pages=87–89|year=2005|isbn=978-981-238-244-3}}</ref> |
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==Occurrence== |
==Occurrence== |
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The representative terrestrial abundance of chlorine-37 is 24.22(4)% of chlorine atoms,<ref name="TICE">{{AtWt TICE 1997}}</ref> with a normal range of 24.14–24.36% of chlorine atoms. When measuring deviations in isotopic composition, the usual reference point is "Standard Mean Ocean Chloride" (SMOC), although a [[NIST]] [[Standard Reference Material]] (975a) also exists. SMOC is known to be around 24.219% chlorine-37 and to have an atomic weight of around 35.4525<ref name="2000Rev">{{AtWt Rev 2000}}</ref> |
The representative terrestrial abundance of chlorine-37 is 24.22(4)% of chlorine atoms,<ref name="TICE">{{AtWt TICE 1997}}</ref> with a normal range of 24.14–24.36% of chlorine atoms. When measuring deviations in isotopic composition, the usual reference point is "Standard Mean Ocean Chloride" (SMOC), although a [[NIST]] [[Standard Reference Material]] (975a) also exists. SMOC is known to be around 24.219% chlorine-37 and to have an atomic weight of around 35.4525.<ref name="2000Rev">{{AtWt Rev 2000}}</ref> |
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There is a known variation in the isotopic abundance of chlorine-37. This heavier isotope tends to be more prevalent in chloride minerals than in aqueous solutions such as |
There is a known variation in the isotopic abundance of chlorine-37. This heavier isotope tends to be more prevalent in chloride minerals than in aqueous solutions such as seawater, although the isotopic composition of [[organochlorine compound]]s can vary in either direction from the SMOC standard in the range of several [[parts per thousand]].<ref name="2000Rev" /> |
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==See also== |
==See also== |
Latest revision as of 01:42, 11 November 2024
General | |
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Symbol | 37Cl |
Names | chlorine-37, 37Cl, Cl-37 |
Protons (Z) | 17 |
Neutrons (N) | 20 |
Nuclide data | |
Natural abundance | 24.23% |
Isotope mass | 36.965903 Da |
Isotopes of chlorine Complete table of nuclides |
Chlorine-37 (37
Cl
), is one of the stable isotopes of chlorine, the other being chlorine-35 (35
Cl
). Its nucleus contains 17 protons and 20 neutrons for a total of 37 nucleons. Chlorine-37 accounts for 24.23% of natural chlorine, chlorine-35 accounting for 75.77%, giving chlorine atoms in bulk an apparent atomic weight of 35.45(1) g/mol.[1]
Remarkably, solar neutrinos were discovered by an experiment (Homestake Experiment) using a radiochemical method based on chlorine-37 transmutation.[2]
Neutrino detection
[edit]One of the historically important radiochemical methods of solar neutrino detection is based on inverse electron capture triggered by the absorption of an electron neutrino.[3] Chlorine-37 transmutes into argon-37 via the reaction[4]
- 37
Cl
+
ν
e → 37
Ar
+
e−
.
Argon-37 then decays via electron capture (half-life 35 d) into chlorine-37 via the reaction
- 37
Ar
+
e−
→ 37
Cl
+
ν
e.
These last reactions involve Auger electrons of specific energies.[3][5] The detection of these electrons confirms that a neutrino event occurred. Detection methods involve several hundred thousand liters of carbon tetrachloride (CCl4) or tetrachloroethylene (C2Cl4) stored in underground tanks.[2][3][6]
Occurrence
[edit]The representative terrestrial abundance of chlorine-37 is 24.22(4)% of chlorine atoms,[7] with a normal range of 24.14–24.36% of chlorine atoms. When measuring deviations in isotopic composition, the usual reference point is "Standard Mean Ocean Chloride" (SMOC), although a NIST Standard Reference Material (975a) also exists. SMOC is known to be around 24.219% chlorine-37 and to have an atomic weight of around 35.4525.[8]
There is a known variation in the isotopic abundance of chlorine-37. This heavier isotope tends to be more prevalent in chloride minerals than in aqueous solutions such as seawater, although the isotopic composition of organochlorine compounds can vary in either direction from the SMOC standard in the range of several parts per thousand.[8]
See also
[edit]References
[edit]- ^ Prohaska, Thomas; et al. (2022-05-25), "Standard atomic weights of the elements 2021 (IUPAC Technical Report)", Pure and Applied Chemistry, vol. 94, no. 5, pp. 573–600, doi:10.1515/pac-2019-0603, ISSN 0033-4545, retrieved 2024-06-07
{{citation}}
: CS1 maint: date and year (link) - ^ a b J.N. Bahcall (1969). "Neutrinos from the Sun". Scientific American. 221 (1): 28–37. Bibcode:1969SciAm.221a..28B. doi:10.1038/scientificamerican0769-28.
- ^ a b c
Sutton, Christine (1992). Spaceship Neutrino. Cambridge University Press. pp. 151–152. ISBN 978-0-521-36404-1. OCLC 25246163.
chlorine-37 neutrino.
- ^
F.H. Shu (1982). The Physical Universe: An Introduction to Astronomy. University Science Books. p. 122. ISBN 978-0-935702-05-7.
chlorine 37 neutrino.
- ^ A.H. Snell, F. Pleasonton (1955). "Spectrometry of the Neutrino Recoils of Argon-37". Physical Review. 100 (5): 1396–1403. Bibcode:1955PhRv..100.1396S. doi:10.1103/PhysRev.100.1396.
- ^ A. Bhatnagar, W. Livingston (2005). Fundamental of Solar Astronomy. World Scientific. pp. 87–89. ISBN 978-981-238-244-3.
- ^ Rosman, K. J. R.; Taylor, P. D. P. (1998), "Isotopic Compositions of the Elements 1997" (PDF), Pure and Applied Chemistry, 70 (1): 217–35, doi:10.1351/pac199870010217
- ^ a b de Laeter, J. R.; et al. (2003), "Atomic Weights of the Elements: Review 2000", Pure and Applied Chemistry, 75 (6): 683–800, doi:10.1351/pac200375060683