radon

(rā`dŏn), gaseous radioactive chemical element; symbol Rn; at. no. 86; mass no. of most stable isotope 222; m.p. about −71&degC;; b.p. −61.8&degC;; density 9.73 grams per liter at STP; valence usually 0. Radon is colorless and the most dense gas known. Chemically unreactive, it is classed as an inert gasinert gas
or noble gas,
any of the elements in Group 18 of the periodic table. In order of increasing atomic number they are: helium, neon, argon, krypton, xenon, and radon. They are colorless, odorless, tasteless gases and were once believed to be entirely inert, i.e.
..... Click the link for more information. in Group 18 of the periodic tableperiodic table,
chart of the elements arranged according to the periodic law discovered by Dmitri I. Mendeleev and revised by Henry G. J. Moseley. In the periodic table the elements are arranged in columns and rows according to increasing atomic number (see the table entitled
..... Click the link for more information. . Synthesis of radon fluoride has been reported.

Radon is highly radioactive and has a short half-life. The chief use of radon is in the treatment of cancer by radiotherapy. It has also found some use (mixed with beryllium) as a neutron source. All naturally occurring radon decays by the emission of alpha particles. The element is found in some spring waters, in streams, and to a very limited extent (about 1 part in 10²¹) in air. Radon is produced by the disintegration of its precursors in minerals, from which it diffuses in small amounts. In homes and other buildings in some areas of the United States, radon produced by the radioactive decay of uranium-238 present in soil and rock can reach levels regarded as dangerous, but the seriousness of the problem is unclear.

Twenty isotopes of radon are known, but only three occur naturally. Radon-222 (half-life 3.82 days) is produced by the decay of radium-226. Radon-220 (half-life 55 sec), also called thoron, is produced in the decay series of thoriumthorium
[from Thor], radioactive chemical element; symbol Th; at. no. 90; mass number of most stable isotope 232; m.p. about 1,750&degC;; b.p. about 4,790&degC;; sp. gr. 11.7 at 20&degC;; valence +4.

Thorium is a soft, ductile, lustrous, silver-white, radioactive metal.
..... Click the link for more information. -232. Radon-219 (half-life 4 sec), also called actinon, is produced in the decay series of uraniumuranium
, radioactive metallic chemical element; symbol U; at. no. 92; mass number of most stable isotope 238; m.p. 1,132&degC;; b.p. 3,818&degC;; sp. gr. 19.1 at 25&degC;; valence +3, +4, +5, or +6.
..... Click the link for more information. -235 (actinouranium). Ernest Rutherford discovered thoron in 1899. F. O. Dorn discovered radon-222 in 1900 and called it radium emanation. In about 1902, F. O. Giesel discovered actinon. In 1908 William Ramsay and R. W. Whytlaw-Gray isolated the element, which they called niton, and studied its physical properties. The name radon was adopted in the 1920s to refer to all the isotopes of the element, although the name emanation and symbol Em have been used.

Radon

A naturally occurring gas, colorless and odorless, that has been shown to cause adverse health effects. Radon gas often enters a structure by seeping through cellar walls and floors.

Radon

(Rn), a radioactive chemical element in group VIII of Mendeleev’s periodic system. Atomic number, 86. One of the inert gases. Three α-radioactive radon isotopes occur in nature as members of the natural radioactive decay series: ^2l9Rn (member of actinouranium series, half-life T_½ = 3.92 sec), ²²⁰Rn (thorium series, T_½ = 54.5 sec), and ²²²Rn (uranium-radium series, T_½ = 3.823 days). The isotope ²¹⁹Rn is also known as actinon (symbol An), and ²²⁰Rn is known as thoron (Tn); ²²²Rn is called true radon and is often designated simply by the symbol Rn.

More than 20 radon isotopes, with mass numbers 201–222, have been obtained artificially through nuclear reactions. In order to synthesize the neutron-deficient radon isotopes with mass numbers 206–212, the Joint Institute for Nuclear Research (Dubna, USSR) has developed a special gas-chromatog-raphy unit, which can produce these isotopes in a radiochemi-cally pure form within a half-hour period.

The discovery of radon was the result of early research on radioactivity. In 1899 the American physicist R. B. Owens found that the decay of Th yields a certain radioactive substance, which can be extracted from solutions containing Th by means of a stream of air. E. Rutherford named this substance emanation (Latin emano, “I flow out”). In 1899, Rutherford, then working in Canada, proved that the thorium emanation discovered by Owens is a radioactive gas. That same year, F. Dorn in Germany and A.-L. Debierne in France announced that emanation (radium emanation → radon) is also formed during radium decay. In 1903 actinium emanation, or actinon (natural radon isotopes are still often called emanations), was also discovered. Thus with radon, scientists encountered —practically for the first time—the existence of several types of atoms in a single element, atoms that were later to be called isotopes. Rutherford, W. Ramsay, and F. Soddy showed that radium emanation is a new chemical element, one belonging to the inert-gas category. The name niton (Latin nitens, “shining”) was proposed because of the element’s ability to luminesce in the condensed state.

Radon is one of the rarest elements. The quantity of radon in the earth’s crust to a depth of 1.6 km amounts to approximately 115 tons. Formed in radioactive ores and minerals, radon gradually makes its way to the surface of the earth and enters the hydrosphere and atmosphere. The average radon concentration in the atmosphere is about 6 × 10^–17 percent (by weight); in sea-water, the concentration can reach 0.001 picocurie per liter.

Under ordinary conditions, radon is a colorless, odorless, and tasteless gas with a boiling point of -61.8°C, a melting point of — 71°C, and a density of approximately 9.9 grams per liter at 0°C. The solubility is approximately 0.5 volume in unit volume of H₂O at 0°C, and with organic solvents the solubility is considerably higher. Since the outer electron shell of the Rn atom contains eight electrons (configuration 6s² 6p6), the element is highly inactive chemically. Like xenon, radon forms a fluoride (possible composition RnF₂), which at 500°C is reduced by hydrogen to elementary radon. As determined by B. A. Nikitin, radon can form clathrates with such compounds as water, phenol, and toluene.

Radon (isotope ²²²Rn) is obtained by passing a stream of gas (nitrogen, argon) through an aqueous solution of a radium salt. After passage through the solution, the gas will contain approximately 10^–5 percent radon. Radon’s good sorption on porous solids (activated carbon) facilitates extraction, and special chemical methods for extraction are also available. The quantities of pure radon obtained do not exceed 1 mm³.

Radon is highly toxic because of its radioactive properties. Upon its decay, nonvolatile radioactive products (isotopes of Po, Bi, and Pb) are formed, which an organism can eliminate only with considerable difficulty. It is therefore necessary to use hermetic boxes and follow safety procedures when working with radon.

Radon is used primarily in medicine. Water containing radon is used in the treatment of diseases of the nervous and cardiovascular systems, respiratory and digestive organs, bones, joints, and muscles and in the treatment of gynecological and metabolic disorders.

The determination of radon concentration in the layer of air at the earth’s surface provides the basis for emanation methods used in geological prospecting. These methods permit an estimation of the U and Th content in soils and in rocks lying near the earth’s surface. Radon is also used in scientific research. The content of U and Th in, for example, rock samples, can be determined from the radioactivity of the radon in equilibrium with these elements. Studies carried out through the emanation method on the structural changes in solids are based on a measurement of the rate of radon formation upon heating solid samples containing radioisotopes that precede radon in the radioactive series ²³²Th and ²³⁵U.

REFERENCES

Bagnall, K. Khimiia redkikh radioaktivnykh elementov. Polonii-aktinii. Moscow, 1960. (Translated from English.)
Berdonosov, S. S. Inertnye gazy vchera i segodnia. Moscow, 1966.
Pertsov, L. A. loniziruiushchie izlucheniia biosfery. Moscow, 1973.
Gusarov, I. I. Radonoterapiia. Moscow, 1974.

S. S. BERDONOSOV

radon

[′rā‚dän] (chemistry) A chemical element, symbol Rn, atomic number 86; all isotopes are radioactive, the longest half-life being 3.82 days for mass number 222; it is the heaviest element of the noble-gas group, produced as a gaseous emanation from the radioactive decay of radium. (nuclear physics) The conventional name for radon-222. Symbolized Rn.

radon

A gaseous emanation produced by the radioactive decay of radium, given off by some soils and rocks; it may collect and constitute a health hazard in buildings with poor ventilation.

radon

a colourless radioactive element of the rare gas group, the most stable isotope of which, radon-222, is a decay product of radium. It is used as an alpha particle source in radiotherapy. Symbol: Rn; atomic no.: 86; half-life of ²²²Rn: 3.82 days; valency: 0; density: 9.73 kg/m³; melting pt.: --71?C; boiling pt.: --61.7?C

radon

[ra´don] a chemical element, atomic number 86, atomic weight 222, symbol Rn. (See Appendix 6.) Radon is a colorless, gaseous, radioactive element produced by the disintegration of radium.

ra·don (Rn),

(rā'don), A gaseous radioactive element, atomic no. 86, resulting from the breakdown of radium; of the isotopes with mass numbers between 198 and 228, only ²²²Rn is medically significant as an α-emitter, with a half-life of 3.8235 days; it is used in the treatment of certain malignancies. Poorly ventilated homes in some parts of the country have accumulated a dangerous amount of naturally occurring radon gas. [from radium]

radon

(rā′dŏn)n. Symbol Rn A colorless, radioactive, inert gaseous element that is formed by the radioactive decay of radium and is used to produce neutrons for research. Its most stable isotope is Rn-222 with a half-life of 3.82 days. A natural source of radiation found in most soils and groundwater, radon poses a serious health threat if inhaled. Atomic number 86; melting point -71°C; boiling point -61.7°C; density of gas 9.73 grams per liter; specific gravity (solid) 4. See Periodic Table.

radon

A naturally occurring radioactive gas in the decay chain of uranium-238 to lead-206, which has a half-life of 3.8 days; it decays into two solid, alpha-particle-emitting daughters. Radon exposure is associated with 13-fold increased risk of lung cancer in non-smoking uranium miners; it also increases the risk of childhood cancer, myeloid leukaemia, renal cell carcinoma, melanoma and prostate cancer.
13,000 annual excess cases of lung cancer in the US are attributed to radon gas. Long-term exposure to 150 Bq/m3 is equivalent to smoking half a pack of cigarettes a day; at ≥ 10.8 pCi/L (400 Bq/m3), the relative risk is 1.8; combined radon exposure and smoking exceed an additive and approach a multiplicative effect.

radon

222Ra Public health A natural radioactive gaseous element, atomic number 86; atomic weight, 211.4 in the 238U → 206Pb decay chain; radon has a T_1⁄2 of 3.8 days, decays into 2 solid α particle-emitting daughters; radon exposure carries a relative risk of 12.7 for lung CA in non-smoking uranium miners and an ↑ risk of childhood CA, myelogenous leukemia, renal cell carcinoma, melanoma, prostate CA. See Radionics, Radium Dial Company.

ra·don

(rā'don) A gaseous radioactive element, atomic no. 86, resulting from the breakdown of radium; ²²²Rn is medically significant as an alpha-emitter with a half-life of 3.8235 days; it is used in the treatment of some malignancies. Poorly ventilated homes in some parts of the United States accumulate a dangerous amount of naturally occurring radon gas.

ra·don

(rā'don) A gaseous radioactive element, resulting from breakdown of radium; some isotopes used to treat malignancies. Poorly ventilated homes in some parts of the U.S. have accumulated a dangerous amount of naturally occurring radon gas.

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Synonyms for radon

noun a radioactive gaseous element formed by the disintegration of radium

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