82
Pb
Lead
Atomic Mass 207.2
Electron Configuration [Xe]6s24f145d106p2
Oxidation States +4, +2
Year Discovered Ancient

Identifiers

Element Name Lead
Element Symbol Pb
InChI InChI=1S/Pb
InChIKey WABPQHHGFIMREM-UHFFFAOYSA-N

Properties

Atomic Weight

[206.14, 207.94]

207.2

207.2

207.2(1)

Electron Configuration

[Xe]6s24f145d106p2

Atomic Radius

Van der Waals Atomic Radius : 202 pm (Van der Waals)

Empirical Atomic Radius : 180pm (Empirical)

Covalent Atomic Radius : 146(5) pm (Covalent)

Oxidation States

+4, +2

4, 3, 2, 1, -1, -2, -4

Ground Level

(1/2,1/2)0

Ionization Energy

7.417 eV

7.4166799 ± 0.0000006 eV

Electronegativity

Pauling Scale Electronegativity : 2.33(Pauling Scale)

Allen Scale Electronegativity : 1.854(Allen Scale)

Electron Affinity

0.36eV

1.03eV

Atomic Spectra

Lines Holdings

Levels Holdings

Physical Description

Solid

Element Classification

Metal

Element Period Number

6

Element Group Number

14

Density

11.342 grams per cubic centimeter

Melting Point

600.61 K (327.46°C or 621.43°F)

327.46°C

Boiling Point

2022 K (1749°C or 3180°F)

1749°C

Estimated Crustal Abundance

1.4×101 milligrams per kilogram

Estimated Oceanic Abundance

3×10-5 milligrams per liter

History

The name derives from the Anglo-Saxon lead, which is of unknown origin. The element was known from prehistoric times. The chemical symbol Pb is derived from the Latin plumbum.

For more information about the natural variations of the atomic weight of lead please read IUPAC Technical Report Variation of lead isotopic composition and atomic weight in terrestrial materials (IUPAC Technical Report) by Z.-K. Zhu et al Pure Appl. Chem. 93, 155-166 (2021).

Lead has been known since ancient times. It is sometimes found free in nature, but is usually obtained from the ores galena (PbS), anglesite (PbSO4), cerussite (PbCO3) and minum (Pb3O4). Although lead makes up only about 0.0013% of the earth's crust, it is not considered to be a rare element since it is easily mined and refined. Most lead is obtained by roasting galena in hot air, although nearly one third of the lead used in the United States is obtained through recycling efforts.

Long known, mentioned in Exodus. The alchemists believed lead to be the oldest metal and associated with the planet Saturn. Native lead occurs in nature, but is rare.

Historical Atomic Weights

Year Atomic Weight (uncertainty) [u] Reference
2020 [206.14, 207.94] https://doi.org/10.1515/pac-2019-0603
1969 207.2(1) https://doi.org/10.1351/pac197021010091
1961 207.19 https://doi.org/10.1021/ja00881a001
1937 207.21 https://doi.org/10.1039/JR9370001900
1931 207.22 https://doi.org/10.1039/JR9310001617
1916 207.20 https://doi.org/10.1021/ja02176a001
1909 207.10 https://doi.org/10.1021/ja01931a001
1902 206.9 https://doi.org/10.1007/BF01370337

Historical Isotopic Abundances

Year Isotope Abundance (uncertainty) Reference
2020 204Pb [0.0000, 0.0158]
2020 206Pb [0.0190, 0.8673]
2020 206Pb [0.0035, 0.2351]
2020 208Pb [0.0338, 0.9775]
2013 204Pb 0.014(6) https://doi.org/10.1515/pac-2015-0503
2013 206Pb 0.241(30) https://doi.org/10.1515/pac-2015-0503
2013 207Pb 0.221(50) https://doi.org/10.1515/pac-2015-0503
2013 208Pb 0.524(70) https://doi.org/10.1515/pac-2015-0503
1975 204Pb 0.014 https://doi.org/10.1351/pac197647010075
1975 206Pb 0.241 https://doi.org/10.1351/pac197647010075
1975 207Pb 0.221 https://doi.org/10.1351/pac197647010075
1975 208Pb 0.524 https://doi.org/10.1351/pac197647010075

Description

Lead is a bluish-white metal of bright luster. It is very soft, highly malleable, ductile, and a poor conductor of electricity. It is very resistant to corrosion; lead pipes bearing the insignia of Roman emperors, used as drains from the baths, are still in service. It is used in containers for corrosive liquids (such as sulfuric acid) and may be toughened by the addition of a small percentage of antimony or other metals.

Users

Lead is a soft, malleable and corrosion resistant material. The ancient Romans used lead to make water pipes, some of which are still in use today. Unfortunately for the ancient Romans, lead is a cumulative poison and the decline of the Roman empire has been blamed, in part, on lead in the water supply. Lead is used to line tanks that store corrosive liquids, such as sulfuric acid (H2SO4). Lead's high density makes it useful as a shield against X-ray and gamma-ray radiation and is used in X-ray machines and nuclear reactors. Lead is also used as a covering on some wires and cables to protect them from corrosion, as a material to absorb vibrations and sounds and in the manufacture of ammunition. Most of the lead used today is used in the production on lead-acid storage batteries, such as the batteries found in automobiles.

Several lead alloys are widely used. Solder, an alloy that is nearly half lead and half tin, is a material with a relatively low melting point that is used to join electrical components, pipes and other metallic items. Type metal, an alloy of lead, tin and antimony, is a material used to make the type used in printing presses and plates. Babbit metal, another lead alloy, is used to reduce friction in bearings.

Lead forms many useful compounds. Lead monoxide (PbO), also known as litharge, is a yellow solid that is used to make some types of glass, such as lead crystal and flint glass, in the vulcanizing of rubber and as a paint pigment. Lead dioxide (PbO2) is a brown material that is used in lead-acid storage batteries. Trilead tetraoxide (Pb3O4), also known as red lead, is used to make a reddish-brown paint that prevents rust on outdoor steel structures. Lead arsenate (Pb3(AsO4)2) has been used as an insecticide although other, less harmful, substances have now largely replaced it. Lead carbonate (PbCO3), also known as cerussite, is a white, poisonous substance that was once widely used as a pigment for white paint. Use of lead carbonate in paints has largely been stopped in favor of titanium oxide (TiO2). Lead sulfate (PbSO4), also known as anglesite, is used in a paint pigment known as sublimed white lead. Lead chromate (PbCrO4), also known as crocoite, is used to produce chrome yellow paint. Lead nitrate (Pb(NO3)2) is used to make fireworks and other pyrotechnics. Lead silicate (PbSiO3) is used to make some types of glass and in the production of rubber and paints.

The metal is very effective as a sound absorber, is used as a radiation shield around X-ray equipment and nuclear reactors, and is used to absorb vibration. White lead, the basic carbonate, sublimed white lead, chrome yellow, and other lead compounds are used extensively in paints, although in recent years the use of lead in paints has been drastically curtailed to eliminate or reduce health hazards.

Lead oxide is used in producing fine "crystal glass" and "flint glass" of a high index of refraction for achromatic lenses. The nitrate and the acetate are soluble salts. Lead salts such as lead arsenate have been used as insecticides, but their use in recent years has been practically eliminated in favor of less harmful organic compounds.

Sources

Lead is obtained chiefly from galena (PbS) by a roasting process. Anglesite, cerussite, and minim are other common lead minerals.

Compounds

Natural lead is a mixture of four stable isotopes: 204Pb (1.48%), 206Pb (23.6%), 207Pb (22.6%), and 208Pb (52.3%). Lead isotopes are the end products of each of the three series of naturally occurring radioactive elements: 206Pb for the uranium series, 207Pb for the actinium series, and 208Pb for the thorium series. Twenty seven other isotopes of lead, all of which are radioactive, are recognized.

Its alloys include solder, type metal, and various antifriction metals. Great quantities of lead, both as the metal and as the dioxide, are used in storage batteries. Much metal also goes into cable covering, plumbing, ammunition, and in the manufacture of lead tetraethyl.

See more information at the Lead compound page.

Element Forms

CID Name Formula SMILES Molecular Weight
5352425 lead Pb [Pb] 207
73212 lead(2+) Pb+2 [Pb+2] 207
6328175 lead-210 Pb [210Pb] 209.98419
6328551 lead-214 Pb [214Pb] 213.99980
6335491 lead-212 Pb [212Pb] 211.99190
6335495 lead-206 Pb [206Pb] 205.97447
6335497 lead-207 Pb [207Pb] 206.97590
6335509 lead-208 Pb [208Pb] 207.97665
6335511 lead-204 Pb [204Pb] 203.97304
6335610 lead-203 Pb [203Pb] 202.97339
6337035 lead-205 Pb [205Pb] 204.97448
6337036 lead-209 Pb [209Pb] 208.98109
6337094 lead-211 Pb [211Pb] 210.98874
6337533 lead-201 Pb [201Pb] 200.9729
6337597 lead-200 Pb [200Pb] 199.9718
6337598 lead-198 Pb [198Pb] 197.97202
6337713 lead-199 Pb [199Pb] 198.97291
6337073 lead-202 Pb [202Pb] 201.97215
6337683 lead-195 Pb [195Pb] 194.97452
133065659 lead-218 Pb [218Pb] 218.017
163203509 lead-212(2+) Pb+2 [212Pb+2] 211.99190
56842200 lead-194 Pb [194Pb] 193.9740
56842201 lead-196 Pb [196Pb] 195.97279
56842202 lead-197 Pb [197Pb] 196.97343
56842203 lead-213 Pb [213Pb] 212.99656

Handling And Storage

Care must be used in handling lead as it is a cumulative poison. Environmental concerns with lead poisoning has resulted in a national program to eliminate the lead in gasoline.

Isotopes

Stable Isotope Count 3

Isotopes in Earth/Planetary Science

The study of lead isotopic compositions is used to model the distribution of pollution in water and on land (Fig. IUPAC.82.1). For example, in one study of Lake Härsvatten in Sweden, the isotope-amount ratio n(206Pb)/n(207Pb) measured at different sediment depths in different areas throughout the lake showed patterns of accumulation of lead pollution. In some cases, these patterns could be related to sediment distribution patterns. Another study used 210Pb (with a half-life of 22.6 years) dating methods to study the vertical accretion of sediments in canals and wetland areas in Louisiana over the last 80 to 100 years [541], [542].

Three of the stable isotopes of lead (206Pb, 207Pb, and 208Pb) are produced by the radioactive decay of isotopes of uranium and thorium (238U, 235U, and 232Th, respectively) and are largely unaffected by environmental and metallurgical processes. Therefore, by examining various isotope-amount ratios of lead isotopes, it is possible to approximate the age of a material. It is also possible to use this information to trace the origins of an object or material [543], [544], [545], [546].

Fig. IUPAC.82.1: Suspended atmospheric dust over California; it is likely that this dust originated in Asia based on lead-isotope studies. (Photo Source: SeaWiFS Project, NASA/Goddard Space Flight Center, and ORBIMAGE, NASA Earth Observatory, 2001) [551], [558].

[541] R. Bindler, I. Renberg, M. L. Brannvall, O. Emteryd, F. El Daoushy. Limnol. Oceanogr.46, 178 (2001).
[542] R. D. DeLaune, J. H. Whitcomb, W. H. Patrick, J. H. Pardue, S. R. Pezeshki. Estuaries12, 247 (1989).
[543] R. W. Hurst. Environ. Geosci.9, 1 (2002).
[544] University of Arizona. Clues To African Archaeology Found In Lead Isotopes, ScienceDaily (2014), Feb. 25; http://www.sciencedaily.com/releases/2006/04/060404204102.htm.
[545] M. Tatsumoto, J. N. Rosholt. Science167, 461 (1970).
[546] R. H. Brill. Philos. Trans. R. Soc. London, Ser. A Mathematical and Physical Sciences.269, 143 (1970).
[551] D. Krotz. Lead Isotopes Yield Clues to How Asian Air Pollution Reaches California, Lawrence Berkeley National Laboratory News Center (2014), Feb. 25; http://newscenter.lbl.gov/feature-stories/2010/12/01/lead-isotopes-air-pollution/.
[558] SeaWiFS Project, NASA/Goddard Space Flight Center, ORBIMAGE. Asian Dust Arrives Over California, NASA Earth Observatory (2014), Feb. 25; http://earthobservatory.nasa.gov/IOTD/view.php?id=1352.

Isotopes in Forensic Science and Anthropology

Different geographic regions may have characteristic terrestrial lead isotopic compositions because of variations in the ages and chemical composition of the rocks and minerals in the local environment. Therefore, lead produced at a particular location can have a unique lead isotopic composition and it is possible to trace the history and origins of pollutants by measuring the relative amounts of the four stable isotopes of lead (208Pb, 207Pb, 206Pb, and 204Pb) (Fig. IUPAC.82.2) [547], [548]. Using isotopic abundance data, the source of this toxic metal can be identified as it moves through air and water and eventually to living systems [547], [549]. Scientists have analyzed lead in air pollution in California and found that it originated from Asia. Airborne particles from China have relatively higher amounts of 208Pb, which distinguishes the lead isotopic signature between airborne particles from Asia and North America. This knowledge could have implications in understanding the mixing of particles in the atmosphere and how pollutants are transported over vast distances [547], [549], [550], [551]. Mapping the distribution of lead pollution by studying 204Pb, 206Pb, 207Pb and 208Pb also allows the identification of those human activities that contribute the highest amounts of lead to the environment [547], [549], [552].

The measurement of the isotopic composition of lead in blood can help to determine the source of this toxic element in the body [553]. Lead is stored in bones and teeth. If a person moves to a different geographical region, the isotopic composition of the lead in the teeth is maintained, recording their place of origin. Bone can store lead for long periods of time (about 20 years), and some skeletal lead may be older and have a different isotopic composition than other skeletal lead. These differences reflect exposure to lead of different origins. By studying the isotope-amount ratio n(206Pb)/n(204Pb) and n(207Pb)/n(206Pb) in bone and teeth, it is possible to determine someone’s place of origin. For example, isotopes of lead were analyzed in the teeth and bones of a human mummy, known as the “Iceman”, to help determine his place of origin [554], [555].

210Pb is a relatively short-lived radioactive isotope of lead that is constantly produced by the decay of 222Rn in the atmosphere. While living, humans naturally incorporate 210Pb from the environment into bones and tissues. The amount of 210Pb in the body reaches equilibrium such that the 210Pb ingested is in equilibrium with the 210Pb that decays. When a person dies, this incorporation of 210Pb ceases and the relative amount of this isotope in the body decreases. Therefore, measurement of the 210Pb activity in a corpse can help determine time of death [556], [557].

Lead isotope-amount ratios n(206Pb)/n(204Pb), n(207Pb)/n(204Pb), and n(208Pb)/n(204Pb)) along with isotope-amount ratio of silver, n(107Ag)/n(109Ag), and isotope-amount ratio of copper n(65Cu)/n(63Cu) have been used to determine the origin of European coins and to investigate the flow of goods in the world market over time [237]. Metals from Peru and Mexico and those from European mining have distinct isotopic signatures that enable the origin of the metal to be determined by examining the isotopic compositions of silver, copper, and lead in the coins. Abundant silver sources mined in Mexico and Peru in the 16 th century were used to mint coins, but were not a major influence in the European coin market until the 18 th century [237].

Fig. IUPAC.82.2: Cross plot of n(²⁰⁶Pb)/n(²⁰⁴Pb) and n(²⁰⁶Pb)/n(²⁰⁷Pb) isotope-amount ratios of lead in selected materials (modified from [548]).

[237] A. M. Desaulty, P. Telouk, E. Albalat, F. Albarede. Proc. Natl. Acad. Sci.108, 9002 (2011).
[547] I. Renberg, M. L. Brännvall, R. Bindler, O. Emteryd. Ambio29, 150 (2000).
[548] T. J. Chow, J. L. Earl. Science169, 577 (1970).
[549] M. K. Reuer, D. J. Weiss. Math. Phys. Eng. Sci.360, 2889 (2002).
[550] S. A. Ewing, J. N. Christensen, S. T. Brown, R. A. Vancuren, S. S. Cliff, D. J. Depaolo. Environ. Sci. Technol.44, 8911 (2010).
[551] D. Krotz. Lead Isotopes Yield Clues to How Asian Air Pollution Reaches California, Lawrence Berkeley National Laboratory News Center (2014), Feb. 25; http://newscenter.lbl.gov/feature-stories/2010/12/01/lead-isotopes-air-pollution/.
[552] D. Cicchella, B. De Vivo, A. Lima, S. Albanese, R. A. R. McGill, R. R. Parrish. Geochem. Explor. Environ. Anal.8, 103 (2008).
[553] R. H. Gwiazda, D. R. Smith. Environ. Health Perspect.108, 1091 (2000).
[554] B. L. Gulson, B. R. Gillings. Environ. Health Perspect.105, 820 (1997).
[555] W. Müller, H. Fricke, A. N. Halliday, M. T. McCulloch, J. A. Wartho. Science302, 862 (2003).
[556] D. R. Smith, J. D. Osterloh, A. R. Flegal. Environ. Health Perspect.104, 60 (1996).
[557] P. Rincon. “Isotopes could improve forensics”, in BBC News Online.

Isotopes in Geochronology

The three natural radioactive-decay chains beginning with 238U, 235U, and 232Th each have comparable half-lives that are much longer than the radioactive isotopes that follow until the production of stable isotopes of 206Pb, 207Pb, and 208Pb, respectively. Therefore, one can measure the relative amounts of the radiogenic isotopes of lead to determine the length of time that has elapsed since uranium and thorium atoms were incorporated into rocks and minerals. Typically, this method is used to date minerals that are tens of millions to billions of years old. The uranium-lead dating method was used to determine some of the first accurate ages of the Earth (about 4.55×109 years) [554], [555], [556].

[554] B. L. Gulson, B. R. Gillings. Environ. Health Perspect.105, 820 (1997).
[555] W. Müller, H. Fricke, A. N. Halliday, M. T. McCulloch, J. A. Wartho. Science302, 862 (2003).
[556] D. R. Smith, J. D. Osterloh, A. R. Flegal. Environ. Health Perspect.104, 60 (1996).

Isotope Mass and Abundance

Isotope Atomic Mass (uncertainty) [u] Abundance (uncertainty)
204Pb 203.973 043(8) [0.0000, 0.0158]
206Pb 205.974 465(8) [0.0190, 0.8673]
207Pb 206.975 897(8) [0.0035, 0.2351]
208Pb 207.976 652(8) [0.0338, 0.9775]
Isotope Atomic Mass (uncertainty) [u] Abundance (uncertainty)
204Pb 203.9730440(13) 0.014(1)
206Pb 205.9744657(13) 0.241(1)
207Pb 206.9758973(13) 0.221(1)
208Pb 207.9766525(13) 0.524(1)

Atomic Mass, Half Life, and Decay

Nuclide Atomic Mass and Uncertainty [u] Half Life and Uncertainty Discovery Year Decay Modes, Intensities and Uncertainties [%]
178Pb 178.003836171 ± 0.000024889 250 us ± 80 2001 α≈100%; β+ ?
179Pb 179.002202492 ± 0.000087203 2.7 ms ± 0.2 2010 α=100%
180Pb 179.997916177 ± 0.000013306 4.1 ms ± 0.3 1996 α=100%
181Pb 180.996660600 ± 0.00009129 39.0 ms ± 0.8 1989 α≈100%; β+ ?
181Pbm 180.996660600 ± 0.00009129 Not-specified
182Pb 181.992673537 ± 0.000012975 55 ms ± 5 1986 α≈100%; β+ ?
183Pb 182.991862527 ± 0.00003111 535 ms ± 30 1980 α≈100%; β+ ?
183Pbm 182.991862527 ± 0.00003111 415 ms ± 20 1980 α≈100%; β+ ?; IT ?
184Pb 183.988135634 ± 0.000013743 490 ms ± 25 1980 α=80±1.1%; β+ ?
185Pb 184.987610000 ± 0.000017364 6.3 s ± 0.4 1975 β+=66±2.5%; α=34±2.5%
185Pbm 184.987610000 ± 0.000017364 4.07 s ± 0.15 1975 α=50±2.5%; β+ ?
186Pb 185.984239409 ± 0.000011813 4.82 s ± 0.03 1972 β+ ?; α=40±0.8%
187Pb 186.983910842 ± 0.000005468 15.2 s ± 0.3 1972 β+=90.5±2%; α=9.5±2%
187Pbm 186.983910842 ± 0.000005468 18.3 s ± 0.3 1972 β+=88±0.2%; α=12±0.2%
188Pb 187.980879079 ± 0.000010868 25.1 s ± 0.1 1972 β+=91.5±0.5%; α=8.5±0.5%
188Pbm 187.980879079 ± 0.000010868 800 ns ± 20 1999 IT=100%
188Pbn 187.980879079 ± 0.000010868 94 ns ± 12 2004 IT=100%
188Pbp 187.980879079 ± 0.000010868 440 ns ± 60 2000 IT=100%
189Pb 188.980843658 ± 0.000015096 39 s ± 8 1972 β+=99.58±1.5%; α=0.42±1.5%
189Pbm 188.980843658 ± 0.000015096 50.5 s ± 2.1 2009 β+≈100%; α≈0.4%; IT ?
189Pbn 188.980843658 ± 0.000015096 26 us ± 5 2005 IT=100%
190Pb 189.978081872 ± 0.000013434 71 s ± 1 1972 β+=99.60±0.4%; α=0.40±0.4%
190Pbm 189.978081872 ± 0.000013434 150 ns ± 14 1998 IT=100%
190Pbn 189.978081872 ± 0.000013434 24.3 us ± 2.1 1998 IT=100%
190Pbp 189.978081872 ± 0.000013434 7.7 us ± 0.3 1985 IT=100%
191Pb 190.978216455 ± 0.000007099 1.33 m ± 0.08 1974 β+≈100%; α=0.51±0.5%
191Pbm 190.978216455 ± 0.000007099 2.18 m ± 0.08 1975 β+≈100%; α≈0.02%
191Pbn 190.978216455 ± 0.000007099 180 ns ± 80 1999 IT=100%
192Pb 191.975789598 ± 0.000006147 3.5 m ± 0.1 1974 β+≈100%; α=0.0059±0.7%
192Pbm 191.975789598 ± 0.000006147 166 ns ± 6 1985 IT=100%
192Pbn 191.975789598 ± 0.000006147 1.09 us ± 0.04 1979 IT=100%
192Pbp 191.975789598 ± 0.000006147 756 ns ± 14 1991 IT=100%
193Pb 192.976135914 ± 0.000011044 4 m [Estimated] 1974 β+= ?
193Pbm 192.976135914 ± 0.000011044 5.8 m ± 0.2 1974 β+=100%
193Pbn 192.976135914 ± 0.000011044 180 ns ± 15 1991 IT=100%
194Pb 193.974011788 ± 0.000018717 10.7 m ± 0.6 1960 β+=100%; α=7.3e-6±2.9%
194Pbm 193.974011788 ± 0.000018717 370 ns ± 13 1972 IT=100%
194Pbn 193.974011788 ± 0.000018717 133 ns ± 7 1986 IT=100%
195Pb 194.974516167 ± 0.000005461 15.0 m ± 1.4 1957 β+=100%
195Pbm 194.974516167 ± 0.000005461 15.0 m ± 1.2 1957 β+=100%; IT ?
195Pbn 194.974516167 ± 0.000005461 10.0 us ± 0.7 1976 IT=100%
195Pbp 194.974516167 ± 0.000005461 95 ns ± 20 1982 IT=100%
196Pb 195.972787552 ± 0.000008277 37 m ± 3 1957 β+=100%; α<3e-5%
196Pbm 195.972787552 ± 0.000008277 <1 us 1973 IT=100%
196Pbn 195.972787552 ± 0.000008277 140 ns ± 14 1973 IT=100%
196Pbp 195.972787552 ± 0.000008277 270 ns ± 4 1973 IT=100%
197Pb 196.973434737 ± 0.000005157 8.1 m ± 1.7 1955 β+=100%
197Pbm 196.973434737 ± 0.000005157 42.9 m ± 0.9 1957 β+=81±0.2%; IT=19±0.2%
197Pbn 196.973434737 ± 0.000005157 1.15 us ± 0.20 1978 IT=100%
198Pb 197.972015450 ± 0.000009393 2.4 h ± 0.1 1955 β+=100%
198Pbm 197.972015450 ± 0.000009393 4.12 us ± 0.07 1972 IT=100%
198Pbn 197.972015450 ± 0.000009393 137 ns ± 10 1989 IT=100%
198Pbp 197.972015450 ± 0.000009393 212 ns ± 4 1973 IT=100%
199Pb 198.972912620 ± 0.000007322 90 m ± 10 1950 β+=100%
199Pbm 198.972912620 ± 0.000007322 12.2 m ± 0.3 1955 IT≈100%; β+= ?
199Pbn 198.972912620 ± 0.000007322 10.1 us ± 0.2 1981 IT=100%
200Pb 199.971818546 ± 0.000010744 21.5 h ± 0.4 1950 ε=100%
200Pbm 199.971818546 ± 0.000010744 456 ns ± 6 1972 IT=100%
200Pbn 199.971818546 ± 0.000010744 198 ns ± 3 1975 IT=100%
201Pb 200.972870431 ± 0.000014758 9.33 h ± 0.03 1950 β+=100%
201Pbm 200.972870431 ± 0.000014758 60.8 s ± 1.8 1952 IT≈100%; β+ ?
201Pbn 200.972870431 ± 0.000014758 508 ns ± 3 1981 IT=100%
202Pb 201.972151613 ± 0.000004075 52.5 ky ± 2.8 1954 ε=100%
202Pbm 201.972151613 ± 0.000004075 3.54 h ± 0.02 1954 IT=90.5±0.5%; β+=9.5±0.5%
202Pbn 201.972151613 ± 0.000004075 100 ns ± 3 1986 IT=100%
202Pbp 201.972151613 ± 0.000004075 108 ns ± 3 1987 IT=100%
203Pb 202.973390617 ± 0.000007036 51.924 h ± 0.015 1942 ε=100%
203Pbm 202.973390617 ± 0.000007036 6.21 s ± 0.08 1955 IT=100%
203Pbn 202.973390617 ± 0.000007036 480 ms ± 7 1977 IT=100%
203Pbp 202.973390617 ± 0.000007036 122 ns ± 4 1988 IT=100%
204Pb 203.973043506 ± 0.000001231 Stable >140Py 1932 IS=1.4±0.6%; α ?
204Pbm 203.973043506 ± 0.000001231 265 ns ± 6 1963 IT=100%
204Pbn 203.973043506 ± 0.000001231 66.93 m ± 0.10 1956 IT=100%
204Pbp 203.973043506 ± 0.000001231 490 ns ± 70 1978 IT=100%
205Pb 204.974481682 ± 0.000001228 17.0 My ± 0.9 1954 ε=100%
205Pbm 204.974481682 ± 0.000001228 24.2 us ± 0.4 1994 IT=100%
205Pbn 204.974481682 ± 0.000001228 5.55 ms ± 0.02 1960 IT=100%
205Pbp 204.974481682 ± 0.000001228 217 ns ± 5 1973 IT=100%
206Pb 205.974465210 ± 0.000001228 Stable >2.5Zy 1927 IS=24.1±3%; α ?
206Pbm 205.974465210 ± 0.000001228 125 us ± 2 1953 IT=100%
206Pbn 205.974465210 ± 0.000001228 202 ns ± 3 1971 IT=100%
207Pb 206.975896821 ± 0.000001231 Stable >1.9Zy 1927 IS=22.1±5%; α ?
207Pbm 206.975896821 ± 0.000001231 806 ms ± 5 1951 IT=100%
208Pb 207.976652005 ± 0.000001232 Stable >2.6Zy 1927 IS=52.4±7%; α ?
208Pbm 207.976652005 ± 0.000001232 535 ns ± 35 1998 IT=100%
209Pb 208.981089978 ± 0.000001875 3.235 h ± 0.005 1940 β-=100%
210Pb 209.984188381 ± 0.000001554 22.20 y ± 0.22 1900 β-=100%; α=1.9e-6±0.4%
210Pbm 209.984188381 ± 0.000001554 92 ns ± 10 2018 IT=100%
210Pbn 209.984188381 ± 0.000001554 201 ns ± 17 1980 IT=100%
211Pb 210.988735288 ± 0.000002426 36.1628 m ± 0.0025 1904 β-=100%
211Pbm 210.988735288 ± 0.000002426 159 ns ± 28 2005 IT=100%
212Pb 211.991895891 ± 0.000001975 10.627 h ± 0.006 1905 β-=100%
212Pbm 211.991895891 ± 0.000001975 6.0 us ± 0.8 1998 IT=100%
213Pb 212.996560796 ± 0.000007465 10.2 m ± 0.3 1964 β-=100%
213Pbm 212.996560796 ± 0.000007465 260 ns ± 20 2020 IT=100%
214Pb 213.999803521 ± 0.000002114 27.06 m ± 0.07 1904 β-=100%
214Pbm 213.999803521 ± 0.000002114 6.2 us ± 0.3 2012 IT=100%
215Pb 215.004661591 ± 0.00005656 142 s ± 11 1998 β-=100%
216Pb 216.008062 ± 0.000215 [Estimated] 1.66 m ± 0.20 2010 β-=100%
216Pbm 216.008062 ± 0.000215 [Estimated] 400 ns ± 40 2012 IT=100%
217Pb 217.013162 ± 0.000322 [Estimated] 19.9 s ± 5.3 2010 β-=100%
218Pb 218.016779 ± 0.000322 [Estimated] 14.8 s ± 6.8 2009 β-=100%
219Pb 219.022136 ± 0.000429 [Estimated] 3 s >300ns [Estimated] 2009 β- ?
220Pb 220.025905 ± 0.000429 [Estimated] 1 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.  Jefferson Lab, U.S. Department of Energy
    LICENSE
    Please see citation and linking information https https://www.jlab.org/privacy-and-security-notice
  5. 5.  Los Alamos National Laboratory, U.S. Department of Energy
  6. 6.  NIST Physical Measurement Laboratory
  7. 7.  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/
  8. 8.  PubChem Elements
    Lead

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