Oxygen-18 Explained

Alternate Names:Ω, Heavy oxygen
Mass Number:18
Symbol:O
Num Neutrons:10
Num Protons:8
Abundance:0.2%
Halflife:stable
Mass:17.9991610
Spin:0

Oxygen-18[1]) is a natural, stable isotope of oxygen and one of the environmental isotopes.

is an important precursor for the production of fluorodeoxyglucose (FDG) used in positron emission tomography (PET). Generally, in the radiopharmaceutical industry, enriched water is bombarded with hydrogen ions in either a cyclotron or linear accelerator, producing fluorine-18. This is then synthesized into FDG and injected into a patient. It can also be used to make an extremely heavy version of water when combined with tritium (hydrogen-3): or . This compound has a density almost 30% greater than that of natural water.[2]

The accurate measurements of rely on proper procedures of analysis, sample preparation and storage.[3]

Paleoclimatology

In ice cores, mainly Arctic and Antarctic, the ratio of to (known as δ) can be used to determine the temperature of precipitation through time. Assuming that atmospheric circulation and elevation has not changed significantly over the poles, the temperature of ice formation can be calculated as equilibrium fractionation between phases of water that is known for different temperatures. Water molecules are also subject to Rayleigh fractionation[4] as atmospheric water moves from the equator poleward which results in progressive depletion of, or lower δ values. In the 1950s, Harold Urey performed an experiment in which he mixed both normal water and water with oxygen-18 in a barrel, and then partially froze the barrel's contents.
The ratio / (δ) can also be used to determine paleothermometry in certain types of fossils. The fossils in question have to show progressive growth in the animal or plant that the fossil represents. The fossil material used is generally calcite or aragonite, however oxygen isotope paleothermometry has also been done of phosphatic fossils using SHRIMP.[5] For example, seasonal temperature variations may be determined from a single sea shell from a scallop. As the scallop grows, an extension is seen on the surface of the shell. Each growth band can be measured, and a calculation is used to determine the probable sea water temperature in comparison to each growth. The equation for this is:

T = A + B \cdot \left(\left(\delta \ce \right) \overbrace\ce^\text - \left(\delta \ce \right) \overbrace\ce^\text \right)

Where T is temperature in Celsius and A and B are constants.

For determination of ocean temperatures over geologic time, multiple fossils of the same species in different stratigraphic layers would be measured, and the difference between them would indicate long term changes.[6]

Plant physiology

In the study of plants' photorespiration, the labeling of atmosphere by oxygen-18 allows for the measurement of oxygen uptake by the photorespiration pathway. Labeling by gives the unidirectional flux of uptake, while there is a net photosynthetic evolution. It was demonstrated that, under preindustrial atmosphere, most plants reabsorb, by photorespiration, half of the oxygen produced by photosynthesis. Then, the yield of photosynthesis was halved by the presence of oxygen in atmosphere.[7] [8]

18F production

Fluorine-18 is usually produced by irradiation of 18O-enriched water (H218O) with high-energy (about 18 MeV) protons prepared in a cyclotron or a linear accelerator, yielding an aqueous solution of 18F fluoride. This solution is then used for rapid synthesis of a labeled molecule, often with the fluorine atom replacing a hydroxyl group. The labeled molecules or radiopharmaceuticals have to be synthesized after the radiofluorine is prepared, as the high energy proton radiation would destroy the molecules.

Large amounts of oxygen-18 enriched water are used in positron emission tomography centers, for on-site production of 18F-labeled fludeoxyglucose (FDG).

An example of the production cycle is a 90-minute irradiation of 2 milliliters of 18O-enriched water in a titanium cell, through a 25 μm thick window made of Havar (a cobalt alloy) foil, with a proton beam having an energy of 17.5 MeV and a beam current of 30 microamperes.

The irradiated water has to be purified before another irradiation, to remove organic contaminants, traces of tritium produced by a 18O(p,t)16O reaction, and ions leached from the target cell and sputtered from the Havar foil.[9]

See also

Notes and References

  1. Web site: Capilla. José E.. Arevalo. Javier Rodriguez. Castaño. Silvino Castaño. Teijeiro. María Fé Díaz. del Moral. Rut Sanchez. Diaz. Javier Heredia. Mapping Oxygen-18 in Meteoric Precipitation over Peninsular Spain using Geostatistical Tools. cedex.es. Ninth Conference on Geostatistics for Environmental Applications. May 8, 2017. Valencia, Spain. September 19, 2012.
  2. Book: Pauling, Linus. 12-7. Heavy Water. https://books.google.com/books?id=EpxSzteNvMYC&pg=PA438. General Chemistry. Dover. 1988. 978-0-486-65622-9. 438. 3rd. registration.
  3. Tsang. Man-Yin. Yao. Weiqi. Tse. Kevin. 2020. Kim. Il-Nam. Oxidized silver cups can skew oxygen isotope results of small samples. Experimental Results. en. 1. e12. 10.1017/exp.2020.15. 2516-712X. free.
  4. Book: Kendall . C. . Caldwell . E.A. . Chapter 2: Fundamentals in Isotope Geochemistry . http://wwwrcamnl.wr.usgs.gov/isoig/isopubs/itchch2.html . Isotope Tracers in Catchment Hydrology . Elsevier Science B.V., Amsterdam. . 1998.
  5. Trotter . J.A. . Williams . I.S. . Barnes . C.R. . Lécuyer . C. . Nicoll . R.S. . Did Cooling Oceans Trigger Ordovician Biodiversification? Evidence from Conodont Thermometry . Science . 321 . 5888 . 550–4 . 2008 . 10.1126/science.1155814. 2008Sci...321..550T . 18653889 . 28224399 .
  6. Book: Kendall . C. . McDonnell . J.J. . Isotope Tracers in Catchment Hydrology . Elsevier Science B.V., Amsterdam. . 1998 .
  7. Gerbaud A, André M . Photosynthesis and photorespiration in whole plants of wheat . Plant Physiol. . 64 . 5 . 735–8 . November 1979 . 16661044 . 543347 . 10.1104/pp.64.5.735.
  8. Canvin DT, Berry JA, Badger MR, Fock H, Osmond CB . Oxygen exchange in leaves in the light . Plant Physiol. . 66 . 2 . 302–7 . August 1980 . 16661426 . 440587 . 10.1104/pp.66.2.302.
  9. Web site: Enriched water-H218O purification to be used in routine 18FDG production . www.iaea.org . 2024-05-20.