Isotopes of hydrogen explained

Hydrogen (1H) has three naturally occurring isotopes, sometimes denoted,, and . and are stable, while has a half-life of years.[1] Heavier isotopes also exist, all of which are synthetic and have a half-life of less than one zeptosecond (10−21 s).[2] [3] Of these, is the least stable, while is the most.

Hydrogen is the only element whose isotopes have different names that remain in common use today: the (or hydrogen-2) isotope is deuterium and the (or hydrogen-3) isotope is tritium. The symbols D and T are sometimes used for deuterium and tritium. The IUPAC accepts the D and T symbols, but recommends using standard isotopic symbols (and) instead to avoid confusion in the alphabetic sorting of chemical formulas. The isotope, with no neutrons, may be called protium to disambiguate. (During the early study of radioactivity, some other heavy radioactive isotopes were given names, but such names are rarely used today.)

List of isotopes

Note that "y" means "year", but "ys" means "yoctosecond" (10−24 second).|-| | 1| 0| | colspan=3 align=center|Stable[4] [5] | 1/2+| colspan="2" style="text-align:center" | [{{val|0.99972}}, {{val|0.99999}}][6] | Protium|-| 2H (D)[7] [8] | 1| 1| | colspan=3 align=center |Stable| 1+| colspan="2" style="text-align:center" | [{{val|0.00001}}, {{val|0.00028}}]| Deuterium|-| 3H (T)| 1| 2| | | β| | 1/2+| Trace[9] || Tritium

|-| | 1| 3| | | n| | 2−|||-| | 1| 4| | | 2n| | (1/2+)|||-| rowspan=2|| rowspan=2|1| rowspan=2|5| rowspan=2|| rowspan=2|| n ?[10] | ?| rowspan=2|2−#| rowspan=2|| rowspan=2||-| 3n ?| ?|-| | 1| 6| #| | 2n ?| ?| 1/2+#| |

Hydrogen-1 (protium)

(atomic mass) is the most common hydrogen isotope, with an abundance of more than 99.98%. Because the nucleus of this isotope consists of only a single proton, it is given the formal name protium.

The proton has never been observed to decay, and hydrogen-1 is therefore considered a stable isotope. Some grand unified theories proposed in the 1970s predict that proton decay can occur with a half-life between and years.[11] If this prediction is found to be true, then hydrogen-1 (and indeed all nuclei now believed to be stable) are only observationally stable., experiments have shown that the minimum mean lifetime of the proton is in excess of years.[12]

Hydrogen-2 (deuterium)

See main article: Deuterium. (atomic mass), the other stable hydrogen isotope, is known as deuterium and contains one proton and one neutron in its nucleus. The nucleus of deuterium is called a deuteron. Deuterium comprises 0.0026–0.0184% (26 ppm to 184 ppm ; by population, not by mass) of hydrogen samples on Earth, with the lower number tending to be found in samples of hydrogen gas and the higher enrichment (0.015% or 150 ppm) typical of ocean water. Deuterium on Earth has been enriched with respect to its initial concentration in the Big Bang and the outer solar system (about 27 ppm, by atom fraction) and its concentration in older parts of the Milky Way galaxy (about 0.0023%, or 23 ppm). Presumably the differential concentration of deuterium in the inner solar system is due to the lower volatility of deuterium gas and compounds, enriching deuterium fractions in comets and planets exposed to significant heat from the Sun over billions of years of solar system evolution.

Deuterium is not radioactive, and does not represent a significant toxicity hazard. Water enriched in molecules that include deuterium instead of protium is called heavy water. Deuterium and its compounds are used as a non-radioactive label in chemical experiments and in solvents for -nuclear magnetic resonance spectroscopy. Heavy water is used as a neutron moderator and coolant for nuclear reactors. Deuterium is also a potential fuel for commercial nuclear fusion.

Hydrogen-3 (tritium)

See main article: Tritium. (atomic mass) is known as tritium and contains one proton and two neutrons in its nucleus. It is radioactive, decaying into helium-3 through β− decay with a half-life of .[1] Trace amounts of tritium occur naturally because of the interaction of cosmic rays with atmospheric gases. Tritium has also been released during nuclear weapons tests. It is used in thermonuclear fusion weapons, as a tracer in isotope geochemistry, and specialized in self-powered lighting devices.

The most common method of producing tritium is by bombarding a natural isotope of lithium, lithium-6, with neutrons in a nuclear reactor.

Tritium can be used in chemical and biological labeling experiments as a radioactive tracer.[13] [14] D-T nuclear fusion uses tritium as its main reactant, along with deuterium, liberating energy through the loss of mass when the two nuclei collide and fuse at high temperatures.

Hydrogen-4

(atomic mass) contains one proton and three neutrons in its nucleus. It is a highly unstable isotope of hydrogen. It has been synthesized in the laboratory by bombarding tritium with fast-moving deuterium nuclei.[15] In this experiment, the tritium nucleus captured a neutron from the fast-moving deuterium nucleus. The presence of the hydrogen-4 was deduced by detecting the emitted protons. It decays through neutron emission into hydrogen-3 (tritium) with a half-life of (or).

In the 1955 satirical novel The Mouse That Roared, the name quadium was given to the hydrogen-4 isotope that powered the Q-bomb that the Duchy of Grand Fenwick captured from the United States.

Hydrogen-5

(atomic mass) is a highly unstable isotope of hydrogen. The nucleus consists of a proton and four neutrons. It has been synthesized in the laboratory by bombarding tritium with fast-moving tritium nuclei.[16] In this experiment, one tritium nucleus captures two neutrons from the other, becoming a nucleus with one proton and four neutrons. The remaining proton may be detected, and the existence of hydrogen-5 deduced. It decays through double neutron emission into hydrogen-3 (tritium) and has a half-life of – the shortest half-life of any known nuclide.[1]

Hydrogen-6

(atomic mass) consists of a proton and five neutrons. It has a half-life of .

Hydrogen-7

(atomic mass) consists of a proton and six neutrons. It was first synthesized in 2003 by a group of Russian, Japanese and French scientists at RIKEN's Radioactive Isotope Beam Factory by bombarding hydrogen with helium-8 atoms. In the resulting reaction, all six of the helium-8 neutrons were donated to the hydrogen's nucleus. The two remaining protons were detected by the "RIKEN telescope", a device composed of several layers of sensors, positioned behind the target of the RI Beam cyclotron. Hydrogen-7 has a half-life of .[1]

Decay chains

and decay directly to, which then decays to the stable isotope . Decay of the heaviest isotopes, and, has not been experimentally observed.

\begin\\\ce &\ce &\ce \\\ce &\ce &\ce \\\ce &\ce &\ce \\\end

Decay times are in yoctoseconds for all these isotopes except, which is expressed in years.

See also

Further reading

Notes and References

  1. Kondev . F. G. . Wang . M. . Huang . W. J. . Naimi . S. . Audi . G. . March 2021 . The NUBASE2020 evaluation of nuclear physics properties \ast. Chinese Physics C . en . 45 . 3 . 030001 . 10.1088/1674-1137/abddae . 2021ChPhC..45c0001K . 233794940 . 1674-1137. free.
  2. Y. B. Gurov. 2004 . Spectroscopy of superheavy hydrogen isotopes in stopped-pion absorption by nuclei . . 68 . 3 . 491–497 . 2005PAN....68..491G . 10.1134/1.1891200 . 122902571 . etal.
  3. A. A. Korsheninnikov. 2003 . Experimental Evidence for the Existence of 7H and for a Specific Structure of 8He . . 90 . 8 . 082501 . 2003PhRvL..90h2501K . 10.1103/PhysRevLett.90.082501 . etal . 12633420.
  4. Unless proton decay occurs.
  5. This and are the only stable nuclides with more protons than neutrons.
  6. Web site: Atomic Weight of Hydrogen. 24 June 2021. CIAAW.
  7. Produced during Big Bang nucleosynthesis.
  8. One of the few stable odd-odd nuclei
  9. Tritium occurs naturally as a cosmogenic nuclide.
  10. Decay mode shown is energetically allowed, but has not been experimentally observed to occur in this nuclide.
  11. Web site: Grand Unified Theories and Proton Decay . Ed Kearns . Boston University . 2009 . 15 .
  12. The SNO+ Collaboration . Anderson . M. . Andringa . S. . Arushanova . E. . Asahi . S. . Askins . M. . Auty . D. J. . Back . A. R. . Barnard . Z. . Barros . N. . Bartlett . D. . 2019-02-20 . Search for invisible modes of nucleon decay in water with the SNO+ detector . Physical Review D . 99 . 3 . 032008 . 10.1103/PhysRevD.99.032008 . 1812.05552 . 2019PhRvD..99c2008A . 96457175 . free.
  13. Web site: Pfizer Japan . Pharmaceuticals and Medical Devices Agency (Japan) . 2.6.5.5B, pp. 6–8 . [<sup>3</sup>H]-Labelled LNP-mRNA . SARS-CoV-2 mRNA Vaccine (BNT162, PF-07302048) . 5 June 2021 . 24 March 2022. https://web.archive.org/web/20220324171847/http://www.pmda.go.jp/drugs/2021/P20210212001/672212000_30300AMX00231_I100_1.pdf#page=16 .
  14. 10.1093/jn/nxaa092. 7330459 . The Journal of Nutrition . Vitamin A Absorption Determined in Rats Using a Plasma Isotope Ratio Method . 2020 . Green . Joanne Balmer . Green . Michael H. . 150 . 7 . 1977–1981 . 32271921.
  15. G. M. Ter-Akopian. 2002 . Hydrogen-4 and Hydrogen-5 from t+t and t+d transfer reactions studied with a 57.5-MeV triton beam . . 610 . 920–924 . 10.1063/1.1470062 . 2002AIPC..610..920T . etal.
  16. A. A. Korsheninnikov. 2001 . Superheavy Hydrogen 5H . . 87 . 9. 92501 . 2001PhRvL..87i2501K . 10.1103/PhysRevLett.87.092501 . 11531562 . etal.