84
Po
Polonium
Atomic Mass 209
Electron Configuration [Xe]6s24f145d106p4
Oxidation States +4, +2
Year Discovered 1898

Identifiers

Element Name Polonium
Element Symbol Po
InChI InChI=1S/Po
InChIKey HZEBHPIOVYHPMT-UHFFFAOYSA-N

Properties

Atomic Weight

209

209

[209]

Electron Configuration

[Xe]6s24f145d106p4

Atomic Radius

Van der Waals Atomic Radius : 197 pm (Van der Waals)

Empirical Atomic Radius : 190pm (Empirical)

Covalent Atomic Radius : 140(4) pm (Covalent)

Oxidation States

+4, +2

6, 5, 4, 2, -1

Ground Level

3P2

Ionization Energy

8.417 eV

8.418070 ± 0.000004 eV

Electronegativity

Pauling Scale Electronegativity : 2(Pauling Scale)

Allen Scale Electronegativity : 2.19(Allen Scale)

Electron Affinity

1.9eV

1.32eV

Atomic Spectra

Lines Holdings

Levels Holdings

Physical Description

Solid

Element Classification

Metal

Element Period Number

6

Element Group Number

16 - Chalcogen

Density

9.32 grams per cubic centimeter

Melting Point

527 K (254°C or 489°F)

254°C

Boiling Point

1235 K (962°C or 1764°F)

962°C

Estimated Crustal Abundance

2×10-10 milligrams per kilogram

Estimated Oceanic Abundance

1.5×10-14 milligrams per liter

History

Polonium was discovered by Marie Sklodowska Curie, a Polish chemist, in 1898. She obtained polonium from pitchblende, a material that contains uranium, after noticing that unrefined pitchblende was more radioactive than the uranium that was separated from it. She reasoned that pitchblende must contain at least one other radioactive element. Curie needed to refine several tons of pitchblende in order to obtain tiny amounts of polonium and radium, another radioactive element discovered by Curie. One ton of uranium ore contains only about 100 micrograms (0.0001 grams) of polonium. Due to its scarcity, polonium is usually produced by bombarding bismuth-209 with neutrons in a nuclear reactor. This forms bismuth-210, which has a half-life of 5 days. Bismuth-210 decays into polonium-210 through beta decay. Milligram amounts of polonium-210 have been produced by this method.

Polonium-210 is a very strong emitter of alpha particles. A single gram of polonium-210 creates 140 Watts of heat energy and is being considered as a lightweight heat source for thermoelectric power for spacecraft. Polonium-210 has a half-life of 138.39 days.

Polonium's most stable isotope, polonium-209, has a half-life of 102 years. It decays into lead-205 through alpha decay. Polonium-209 is available from Oak Ridge National Laboratory at the cost of about $3200 per microcurie.

Named after Poland, native country of Madam Curie. Polonium, also called Radium F, was the first element discovered by Curie in 1898 while seeking the cause of radioactivity of pitchblend from Joachimsthal, Bohemia. The electroscope showed it separating with bismuth.

Description

Polonium-210 is a low-melting, fairly volatile metal, 50% of which is vaporized in air in 45 hours at 55°C. It is an alpha emitter with a half-life of 138.39 days. A milligram emits as many alpha particles as 5 g of radium.

The energy released by its decay is so large (140W/g) that a capsule containing about half a gram reaches a temperature above 500C. The capsule also presents a contact gamma-ray dose rate of 0.012 Gy/h. A few curies (1 curie = 3.7 x 1010Bq) of polonium exhibit a blue glow, caused by excitation of the surrounding gas.

Polonium is readily dissolved in dilute acids, but is only slightly soluble in alkali. Polonium salts of organic acids char rapidly; halide amines are reduced to the metal.

Users

Polonium can be used to eliminate static electricity in machinery that is caused by processes such as the rolling of paper, wire or sheet metal, although other materials which emit beta particles are more commonly used for this purpose. Polonium is also used in brushes for removing dust from photographic films, although the polonium must be carefully sealed to protect the user from contamination. Polonium is also combined with beryllium to form neutron sources.

Because almost all alpha radiation is stopped within the solid source and its container, giving up its energy, polonium has attracted attention for uses as a lightweight heat source for thermoelectric power in space satellites.

Polonium can be mixed or alloyed with beryllium to provide a source of neutrons. The element has been used in devices for eliminating static charges in textile mills, etc.; however, beta sources are both more commonly used and less dangerous. It is also used on brushes for removing dust from photographic films. The polonium for these is carefully sealed and controlled, minimizing hazards to the user.

Sources

Polonium is a very rare natural element. Uranium ores contain only about 100 micrograms of the element per ton. Its abundance is only about 0.2% of that of radium.

In 1934, scientists discovered that when they bombarded natural bismuth (209Bi) with neutrons, 210Bi, the parent of polonium, was obtained. Milligram amounts of polonium may now be prepared this way, by using the high neutron fluxes of nuclear reactors.

Compounds

See more information at the Polonium compound page.

Element Forms

CID Name Formula SMILES Molecular Weight
6328143 polonium Po [Po] 208.98243
6328544 polonium-210 Po [210Po] 209.98287
6328554 polonium-218 Po [218Po] 218.00897
6335815 polonium-216 Po [216Po] 216.00191
6337584 polonium-215 Po [215Po] 214.99942
6337588 polonium-211 Po [211Po] 210.98665
24755505 polonium-209 Po [209Po] 208.98243
6337586 polonium-207 Po [207Po] 206.98159
24755511 polonium-200 Po [200Po] 199.98181
24755506 polonium-208 Po [208Po] 207.98125
24755508 polonium-204 Po [204Po] 203.9803
24755510 polonium-201 Po [201Po] 200.98226
6337600 polonium-203 Po [203Po] 202.98142
6337601 polonium-205 Po [205Po] 204.9812
24755507 polonium-206 Po [206Po] 205.98047
24755509 polonium-202 Po [202Po] 201.98074
24755512 polonium-199 Po [199Po] 198.98364
24755513 polonium-198 Po [198Po] 197.9834
24755514 polonium-197 Po [197Po] 196.9856
24755515 polonium-196 Po [196Po] 195.98554
24755516 polonium-195 Po [195Po] 194.98807
24755517 polonium-194 Po [194Po] 193.9882
24755518 polonium-193 Po [193Po] 192.9911
24755519 polonium-192 Po [192Po] 191.9913
24755520 polonium-191 Po [191Po] 190.99456
24755521 polonium-190 Po [190Po] 189.9951
24755522 polonium-217 Po [217Po] 217.00632

Handling And Storage

Polonium-210 is very dangerous to handle in even milligram or microgram amounts, and special equipment and strict control is necessary. Damage arises from the complete absorption of the energy of the alpha particle into tissue.

The maximum permissible body burden for ingested polonium is only 0.03 microcuries, which represents a particle weighing only 6.8 x 10-12 g. Weight for weight it is about 2.5 x 1011 times as toxic as hydrocyanic acid. The maximum allowable concentration for soluble polonium compounds in air is about 2 x 10-11 microcuries/cm3.

Isotopes

Stable Isotope Count 0
Summary Twenty five isotopes of polonium are known, with atomic masses ranging from 194 to 218. Polonium-210 is the most readily available. Isotopes of mass 209 (half-life 103 years) and mass 208 (half-life 2.9 years) can be prepared by alpha, proton, or deuteron bombardment of lead or bismuth in a cyclotron, but these are expensive to produce.

Isotopes in Industry

210Po (with a half-life of 138 days) is used as static eliminator to remove static electricity in machinery. This is useful in machinery that produces electricity easily, for example, via rolling paper, manufacturing sheet plastics, and spinning synthetic fibers, which all readily produce static [75], [563]. 210Po can also make use of its static eliminating properties when used in brushes that function to clean camera lenses and photographic films (Fig. IUPAC.84.1) [75]. 210Po has been used to manufacture atomic weapons. When combined with beryllium, polonium can act as a neutron-producing initiator. However, because of its short half-life, 210Po is no longer used in this manner [75].

Fig. IUPAC.84.1: Staticmaster™ Alpha Ionizing Brushes for cleaning optical surfaces and photographic films have a soft, non-abrasive brush and a ²¹⁰Po cartridge. (Photo Source: Reston Stable Isotope Laboratory of the U.S. Geological Survey) [564].

[75] J. Peterson, M. McDonell, L. Haroun, F. Monette, R. D. Hildebrand, A. Taboas. Radiological and Chemical Fact Sheets to Support Health Risk Analyses for Contaminated Areas, Prepared by Argonne National Laboratory Environmental Science Division in collaboration with U.S. Department of Energy, Richland Operations Office and Chicago Operations Office (2014), Feb. 22; http://www.remm.nlm.gov/ANL_ContaminantFactSheets_All_070418.pdf.
[563] United States Nuclear Regulatory Commission. Backgrounder on Polonium-210, United States Nuclear Regulatory Commission (2017), April 8; http://www.nrc.gov/reading-rm/doc-collections/fact-sheets/polonium.html.
[564] Reston Stable Isotope Laboratory. Staticmaster™ Alpha Ionizing Brush.

Isotope Mass and Abundance

Isotope Atomic Mass (uncertainty) [u] Abundance (uncertainty)
209Po 208.9824308(20)
210Po 209.9828741(13)

Atomic Mass, Half Life, and Decay

Nuclide Atomic Mass and Uncertainty [u] Half Life and Uncertainty Discovery Year Decay Modes, Intensities and Uncertainties [%]
186Po 186.004403174 ± 0.000019622 34 us ± 12 2005 α≈100%; p ?
187Po 187.003031482 ± 0.00003503 1.40 ms ± 0.25 2005 α≈100%; β+ ?
187Pom 187.003031482 ± 0.00003503 0.5 ms 2006 α≈100%; β+ ?
188Po 187.999415586 ± 0.000021438 270 us ± 30 1999 α≈100%; β+ ?
189Po 188.998473425 ± 0.000023681 3.5 ms ± 0.5 1999 α≈100%; β+ ?
190Po 189.995101731 ± 0.000014131 2.45 ms ± 0.05 1996 α=100%; β+ ?
191Po 190.994558494 ± 0.000007624 22 ms ± 1 1993 α≈100%; β+ ?
191Pom 190.994558494 ± 0.000007624 93 ms ± 3 1999 α≈100%; β+ ?
192Po 191.991340274 ± 0.000011416 32.2 ms ± 0.3 1977 α≈100%; β+ ?
192Pom 191.991340274 ± 0.000011416 580 ns ± 100 1999 IT=100%
193Po 192.991062421 ± 0.000015599 399 ms ± 34 1967 α≈100%; β+ ?
193Pom 192.991062421 ± 0.000015599 245 ms ± 11 1981 α≈100%; β+ ?
194Po 193.988186058 ± 0.00001386 392 ms ± 4 1967 α≈100%; β+ ?
194Pom 193.988186058 ± 0.00001386 12.9 us ± 0.5 1999 IT=100%
195Po 194.988065781 ± 0.000006486 4.64 s ± 0.09 1967 α=94±0.4%; β+ ?
195Pom 194.988065781 ± 0.000006486 1.92 s ± 0.02 1967 α≈100%; β+ ?; IT ?
196Po 195.985540722 ± 0.000005778 5.63 s ± 0.07 1967 α=94±0.5%; β+ ?
196Pom 195.985540722 ± 0.000005778 856 ns ± 17 1995 IT=100%
197Po 196.985621939 ± 0.000010585 53.6 s ± 0.9 1965 β+ ?; α=44±0.7%
197Pom 196.985621939 ± 0.000010585 25.8 s ± 0.1 1967 α=84±0.9%; β+ ?; IT ?
198Po 197.983388753 ± 0.000018705 1.760 m ± 0.024 1965 α=57±0.2%; β+=43±0.2%
198Pom 197.983388753 ± 0.000018705 200 ns ± 20 1990 IT=100%
198Pon 197.983388753 ± 0.000018705 750 ns ± 50 1990 IT=100%
199Po 198.983640445 ± 0.000005828 5.47 m ± 0.15 1965 β+=92.5±0.3%; α=7.5±0.3%
199Pom 198.983640445 ± 0.000005828 4.17 m ± 0.05 1964 β+=73.5±1%; α=24±0.1%; IT=2.5±1%
200Po 199.981812355 ± 0.000008136 11.51 m ± 0.08 1951 β+=88.9±0.3%; α=11.1±0.3%
200Pom 199.981812355 ± 0.000008136 100 ns ± 10 1985 IT=100%
200Pon 199.981812355 ± 0.000008136 268 ns ± 3 1985 IT=100%
201Po 200.982263799 ± 0.000005305 15.6 m ± 0.1 1951 β+=98.87±0.3%; α=1.13±0.3%
201Pom 200.982263799 ± 0.000005305 8.96 m ± 0.12 1962 IT=56.2±1.2%; β+=41.4±0.7%; α=2.4±0.5%
202Po 201.980738934 ± 0.000009307 44.6 m ± 0.4 1951 β+=98.08±0.7%; α=1.92±0.7%
202Pom 201.980738934 ± 0.000009307 110 ns ± 15 1971 IT=100%
203Po 202.981416072 ± 0.000004981 36.7 m ± 0.5 1951 β+=99.89±0.2%; α=0.11±0.2%
203Pom 202.981416072 ± 0.000004981 45 s ± 2 1969 IT≈100%; α ?
203Pon 202.981416072 ± 0.000004981 >200 ns 1986 IT=100%
204Po 203.980310078 ± 0.000010811 3.519 h ± 0.012 1951 β+=99.33±0.3%; α=0.67±0.3%
204Pom 203.980310078 ± 0.000010811 158.6 ns ± 1.8 1970 IT=100%
205Po 204.981190006 ± 0.000010798 1.74 h ± 0.08 1951 β+=99.960±1.2%; α=0.040±1.2%
205Pom 204.981190006 ± 0.000010798 310 ns ± 60 1960 IT=100%
205Pon 204.981190006 ± 0.000010798 645 us ± 20 1962 IT=100%
205Pop 204.981190006 ± 0.000010798 57.4 ms ± 0.9 1973 IT=100%
205Poq 204.981190006 ± 0.000010798 115 ns ± 10 1985 IT=100%
206Po 205.980473662 ± 0.000004306 8.8 d ± 0.1 1947 β+=94.55±0.5%; α=5.45±0.5%
206Pom 205.980473662 ± 0.000004306 232 ns ± 4 1970 IT=100%
206Pon 205.980473662 ± 0.000004306 1.05 us ± 0.06 1970 IT=100%
207Po 206.981593334 ± 0.000007148 5.80 h ± 0.02 1947 β+≈100%; α=0.021±0.2%
207Pom 206.981593334 ± 0.000007148 205 ns ± 10 1963 IT=100%
207Pon 206.981593334 ± 0.000007148 49 us ± 4 1962 IT=100%
207Pop 206.981593334 ± 0.000007148 2.79 s ± 0.08 1961 IT=100%
208Po 207.981246035 ± 0.000001795 2.898 y ± 0.002 1947 α≈100%; β+=0.0042±0.4%
208Pom 207.981246035 ± 0.000001795 373 ns ± 8 1968 IT=100%
209Po 208.982430361 ± 0.000001909 124 y ± 3 1949 α=99.546±0.7%; β+=0.454±0.7%
209Pom 208.982430361 ± 0.000001909 119 ns ± 4 1974 IT=100%
210Po 209.982873686 ± 0.00000123 138.376 d ± 0.002 1898 α=100%
210Pom 209.982873686 ± 0.00000123 98.9 ns ± 2.5 1968 IT=100%
210Pon 209.982873686 ± 0.00000123 263 ns ± 5 1985 IT=100%
211Po 210.986653171 ± 0.000001347 516 ms ± 3 1913 α=100%
211Pom 210.986653171 ± 0.000001347 25.2 s ± 0.6 1954 α=99.984±0.4%; IT=0.016±0.4%
211Pon 210.986653171 ± 0.000001347 243 ns ± 21 1998 IT≈100%; α ?
211Pop 210.986653171 ± 0.000001347 2.8 us ± 0.7 1998 IT≈100%; α ?
212Po 211.988867982 ± 0.000001237 294.4 ns ± 0.8 1906 α=100%
212Pom 211.988867982 ± 0.000001237 45.1 s ± 0.6 1962 α=99.93±0.2%; IT ?
213Po 212.992857154 ± 0.000003277 3.705 us ± 0.001 1947 α=100%
214Po 213.995201287 ± 0.000001556 163.47 us ± 0.03 1912 α=100%
215Po 214.999418385 ± 0.000002276 1.781 ms ± 0.005 1911 α=100%; β-=2.3e-4±0.2%
216Po 216.001913416 ± 0.000001948 144.0 ms ± 0.6 1910 α=100%; 2β- ?
217Po 217.006316145 ± 0.000007025 1.53 s ± 0.05 1956 α=97.5±1.4%; β-=2.5±1.4%
218Po 218.008971234 ± 0.000002112 3.097 m ± 0.012 1904 α=99.980±0.2%; β-=0.020±0.2%
219Po 219.013614000 ± 0.000017 10.3 m ± 1.0 1998 β-=71.8±2%; α=28.2±2%
220Po 220.016386000 ± 0.000019 10 s >300ns [Estimated] 1998 β- ?
221Po 221.021228000 ± 0.000021 2.2 m ± 0.7 2010 β-=100%
222Po 222.024140000 ± 0.000043 9.1 m ± 7.2 2010 β-=100%
223Po 223.029070 ± 0.00021 [Estimated] 6 s >300ns [Estimated] 2010 β- ?
224Po 224.032110 ± 0.00021 [Estimated] 3 m >300ns [Estimated] 2010 β- ?
225Po 225.037123 ± 0.000322 [Estimated] 10 s >300ns [Estimated] 2010 β- ?
226Po 226.040310 ± 0.00043 [Estimated] 1 m >300ns [Estimated] 2010 β- ?
227Po 227.045390 ± 0.00043 [Estimated] 2 s >300ns [Estimated] 2010 β- ?

Information Sources

  1. 1.  PubChem
  2. 2.  Atomic Mass Data Center (AMDC), International Atomic Energy Agency (IAEA)
  3. 3.  IUPAC Commission on Isotopic Abundances and Atomic Weights (CIAAW)
  4. 4.  IUPAC Periodic Table of the Elements and Isotopes (IPTEI)
    LICENSE
    Copyright (c) 2020 International Union of Pure and Applied Chemistry. The International Union of Pure and Applied Chemistry (IUPAC) contribution within Pubchem is provided under a CC-BY-NC-ND 4.0 license, unless otherwise stated.
    https://creativecommons.org/licenses/by-nc-nd/4.0/
  5. 5.  Jefferson Lab, U.S. Department of Energy
    LICENSE
    Please see citation and linking information https https://www.jlab.org/privacy-and-security-notice
  6. 6.  Los Alamos National Laboratory, U.S. Department of Energy
  7. 7.  NIST Physical Measurement Laboratory
  8. 8.  PubChem Elements
    Polonium

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