55
Cs
Cesium
Atomic Mass 132.90545196
Electron Configuration [Xe]6s1
Oxidation States +1
Year Discovered 1860

Identifiers

Element Name Cesium
Element Symbol Cs
InChI InChI=1S/Cs
InChIKey TVFDJXOCXUVLDH-UHFFFAOYSA-N

Properties

Atomic Weight

132.905 451 96(6)

132.90545196

132.9

132.90545196(6)

Electron Configuration

[Xe]6s1

Atomic Radius

Van der Waals Atomic Radius : 343 pm (Van der Waals)

Empirical Atomic Radius : 260pm (Empirical)

Covalent Atomic Radius : 244(11) pm (Covalent)

Oxidation States

+1

+1, -1 ​(a strongly basic oxide)

Ground Level

2S1/2

Ionization Energy

3.894 eV

3.89390572743 ± 0.00000000017 eV

Electronegativity

Pauling Scale Electronegativity : 0.79(Pauling Scale)

Allen Scale Electronegativity : 0.659(Allen Scale)

Electron Affinity

0.472eV

0.39eV

Atomic Spectra

Lines Holdings

Levels Holdings

Physical Description

Solid

Element Classification

Metal

Element Period Number

6

Element Group Number

1 - Alkali Metal

Density

1.93 grams per cubic centimeter

Melting Point

301.59 K (28.44°C or 83.19°F)

28.5°C

Boiling Point

944 K (671°C or 1240°F)

671°C

Estimated Crustal Abundance

3 milligrams per kilogram

Estimated Oceanic Abundance

3×10-4 milligrams per liter

History

The name derives from the Latin caesius for "sky blue", which was the colour of the caesium line in the spectroscope. Caesium was discovered by the German chemist Robert Wilhelm Bunsen and the German physicist Gustav Robert Kirchhoff in 1860. It was first isolated by the German chemist Carl Setterberg in 1882.

Cesium was discovered by Robert Wilhelm Bunsen and Gustav Robert Kirchhoff, German chemists, in 1860 through the spectroscopic analysis of Durkheim mineral water. They named cesium after the blue lines they observed in its spectrum. Today, cesium is primarily obtained from the mineral pollucite (CsAlSi2O6). Obtaining pure cesium is difficult since cesium ores are frequently contaminated with rubidium, an element that is chemically similar to cesium. To obtain pure cesium, cesium and rubidium ores are crushed and heated with sodium metal to 650°C, forming an alloy that can then be separated with a process known as fractional distillation. Metallic cesium is too reactive to easily handle and is usually sold in the form of cesium azide (CsN3). Cesium is recovered from cesium azide by heating it.

From the Latin word caesius, sky blue. Cesium was discovered spectroscopically in 1860 by Bunsen and Kirchhoff in mineral water from Durkheim.

Historical Atomic Weights

Year Atomic Weight (uncertainty) [u] Reference
2013 132.905 451 96(6) https://doi.org/10.1515/pac-2015-0305
2005 132.905 4519(2) https://doi.org/10.1351/pac200678112051
1995 132.905 45(2) https://doi.org/10.1351/pac199668122339
1985 132.905 43(5) https://doi.org/10.1351/pac198658121677
1971 132.9054(1) https://doi.org/10.1351/pac197230030637
1969 132.9055(1) https://doi.org/10.1351/pac197021010091
1961 132.905 https://doi.org/10.1021/ja00881a001
1934 132.91 https://doi.org/10.1039/JR9340000499
1909 132.81 https://doi.org/10.1021/ja01931a001
1904 132.9 https://doi.org/10.1021/ja01991a001
1902 133 https://doi.org/10.1007/BF01370337

Historical Isotopic Abundances

Year Isotope Abundance (uncertainty) Reference
1975, 133Cs, 1, doi:10.1351/pac197647010075

Description

The metal is characterized by a spectrum containing two bright lines in the blue along with several others in the red, yellow, and green wavelengths. It is silvery white, soft, and ductile. It is the most electropositive and most alkaline element.

Cesium, gallium, and mercury are the only three metals that are liquid at room temperature. Cesium reacts explosively with cold water, and reacts with ice at temperatures above -116C. Cesium hydroxide, the strongest base known, attacks glass.

Users

Cesium has the second lowest melting point of all metallic elements, which limits its uses. Cesium readily combines with oxygen and is used as a getter, a material that combines with and removes trace gases from vacuum tubes. Cesium is also used in atomic clocks, in photoelectric cells and as a catalyst in the hydrogenation of certain organic compounds. Since it is easily ionized and has a high mass, cesium ions may one day be used as a propellant in ion engines on spacecraft.

Cesium reacts violently with water and ice, forming cesium hydroxide (CsOH). Cesium hydroxide is the strongest base known and will attack glass. Cesium chloride (CsCl) and cesium nitrate (CsNO3) are cesium's most common compounds and are primarily used in the production of other chemicals.

Because of it has great affinity for oxygen, the metal is used as a "getter" in electron tubes. It is also used in photoelectric cells, as well as a catalyst in the hydrogenation of certain organic compounds.

The metal has recently found application in ion propulsion systems. Cesium is used in atomic clocks, which are accurate to 5 s in 300 years. Its chief compounds are the chloride and the nitrate.

Sources

Cesium, an alkali metal, occurs in lepidolite, pollucte (a hydrated silicate of aluminum and cesium), and in other sources. One of the world's richest sources of cesium is located at Bernic Lake, Manitoba. The deposits are estimated to contain 300,000 tons of pollucite, averaging 20% cesium.

It can be isolated by elecytrolysis of the fused cyanide and by a number of other methods. Very pure, gas-free cesium can be prepared by thermal decomposition of cesium azide.

Compounds

See more information at the Cesium compound page.

Element Forms

CID Name Formula SMILES Molecular Weight
5354618 cesium Cs [Cs] 132.9054520
5486527 cesium-137 Cs [137Cs] 136.907089
104967 cesium(1+) Cs+ [Cs+] 132.9054520
5492303 cesium-131 Cs [131Cs] 130.905468
6335485 cesium-134 Cs [134Cs] 133.9067185
6335805 cesium-135 Cs [135Cs] 134.905977
6337065 cesium-129 Cs [129Cs] 128.90607
6337068 cesium-144 Cs [144Cs] 143.9321
6337088 cesium-132 Cs [132Cs] 131.90644
6335316 cesium-136 Cs [136Cs] 135.90731
6337069 cesium-127 Cs [127Cs] 126.90742
6337089 cesium-125 Cs [125Cs] 124.90973
6337090 cesium-138 Cs [138Cs] 137.91102
6337572 cesium-130 Cs [130Cs] 129.90671
44150505 cesium-139 Cs [139Cs] 138.91336
181313 cesium-137(1+) Cs+ [137Cs+] 136.907089
6337580 cesium-143 Cs [143Cs] 142.92735
44148233 cesium-141 Cs [141Cs] 140.92005
10197717 cesium-134(1+) Cs+ [134Cs+] 133.9067185
51352725 cesium-132(1+) Cs+ [132Cs+] 131.90644
91865105 cesium-131(1+) Cs+ [131Cs+] 130.905468

Isotopes

Stable Isotope Count 1
Summary Cesium has more isotopes than any element32with masses ranging from 114 to 145.

Isotopes in Biology

137Cs (with a half-life of 30 years) can be used as a tracer in fungal mycelia (an extensive matrix of underground hyphae (stems of growth from a fungus)) to monitor the immobilization of this radioactive caesium isotope. After the nuclear reactor accident at Chernobyl, large quantities of 137Cs were released as fission products into the environment. Areas with large fungal populations and fungal mycelia seemed to immobilize the 137Cs isotope, which limited the spread of the radioactive isotope [399], [400].

[399] S. N. Gray, J. Dighton, S. Olsson, D. H. Jennings. New Phytol.129, 449 (1995).
[400] J. Dighton, G. M. Clint, J. Poskitt. Mycol. Res.95, 1052 (1991).

Isotopes in Earth/Planetary Science

River floodplains are an important site for storing suspended sediments and contaminants transferred from upstream catchments. 137Cs measurements of floodplain sediments provide a technique for estimating overbank sediment deposition, and it can provide information on spatial patterns of sediment deposition (Fig. IUPAC.55.1) [401], [402], [403].

Fig. IUPAC.55.1: Topography and excess ¹³⁷Cs inventory as a function of surface sediment size, less than 63 μm (modified from Walling and He [403]).

[401] R. H. Gardner, W. W. Hargrove, D. A. Levine, S. M. Pearson, K. A. Rose. Spatial Analysis of Cesium in Sediments of Watts Bar Reservoir, Oak Ridge National Laboratory (2014), Feb. 27; http://research.esd.ornl.gov/CRERP/WATTSBAR/INDEX.HTM.
[402] C. R. Olsen, I. L. Larson, P. D. Lowry, C. R. Moriones, C. J. Ford, K. C. Dearstone, R. R. Turner, B. L. Kimmel, C. C. Brandt. Transport and Accumulation of Cesium-137 and Mercury in the Clinch River and Watts Bar Reservoir system, ORNL/ER-7, Oak Ridge National Laboratory, Oak Ridge, TN (1992).
[403] D. E. Walling, Q. He. Catena29, 263 (1997).

Isotopes in Geochronology

Nuclear fission of 235U (or other fissionable materials) yields 137Cs as a product. Although 137Cs is not naturally present in the environment, it can be collected from nuclear reactor processing and then used as an environmental tracer. 137Cs adheres tightly to porous sediments and will follow the movement of the sediment. By exposing sediments to 137Cs and allowing this combination to move dynamically, gamma ray spectrometry can then be used to measure the activity of 137Cs and monitor the movement of the radioactive sediments [404], [405], [406].

137Cs dating of sediments not older than 60 years is useful in natural and artificial lakes and other environments because of its widespread production and release during atmospheric nuclear weapons testing, which began in the late 1940s, plus subsequent releases, such as during the accident at the Chernobyl nuclear reactor in April 1986. The 137Cs concentration profile in a sediment core can be matched with the historical record of 137Cs release to determine the approximate age profile of the sediment [406], [407].

[404] W. G. Winn. J. Radioanal. Nucl. Chem.195, 345 (1995).
[405] A. V. Chesnokov, A. P. Govorun, F. V. N., O. P. Ivanov, V. I. Liksonov, V. N. Potapov, S. B. Shcherbak, S. V. Smirnov, L. I. Urutskoev. Nucl. Instrm. Methods Phys. Res. Section A: Accelerators, Spectrometers, Detectors and Associated Equipment.420, 336 (1999).
[406] A. Albrecht, R. Reiser, A. Lück, J. M. A. Stoll, W. Giger. Environ. Sci. Technol.32, 1882 (1998).
[407] M. S. Humphries, A. Kindness, W. N. Ellery, J. C. Hughes, C. R. Benitez-Nelson. Geomorphology119, 88 (2010).

Isotopes in Industry

High-energy gamma rays from 137Cs serve as food irradiation devices to remove bacteria and other harmful microorganisms (living single celled organisms such as virus, algae and fungus) from food. Although 137Cs is not used commercially for large-scale food irradiation, it has been proposed that it can be used this way. Gamma rays from the radioactive 137Cs destroy the DNA of organisms to enable foods to last longer (i.e. irradiation of fruits and vegetables stops the ripening process) and be contamination free [408], [409].

[408] D. W. Hayer. J. Food Quality13, 147 (1990).
[409] United States General Accounting Office. Food Irradiation: Available Research Indicates that Benefits Outweigh the Risks, GAO/RCED-00-217, GAO (2000).

Isotope Mass and Abundance

Isotope Atomic Mass (uncertainty) [u] Abundance (uncertainty)
133Cs 132.905 451 96(6) 1
Isotope Atomic Mass (uncertainty) [u] Abundance (uncertainty)
133Cs 132.9054519610(80) 1

Atomic Mass, Half Life, and Decay

Nuclide Atomic Mass and Uncertainty [u] Half Life and Uncertainty Discovery Year Decay Modes, Intensities and Uncertainties [%]
111Cs 110.953945 ± 0.000215 [Estimated] 1 us [Estimated] p ?
112Cs 111.950172 ± 0.000124 [Estimated] 490 us ± 30 1994 p≈100%; α<0.26%
113Cs 112.944428484 ± 0.000009207 16.94 us ± 0.09 1984 p=100%
114Cs 113.941292244 ± 0.000091323 570 ms ± 20 1978 β+≈100%; α=0.018±0.6%; β+p=8.7±1.3%; β+α=0.19±0.3%
115Cs 114.935910 ± 0.00011 [Estimated] 1.4 s ± 0.8 1978 β+=100%; β+p≈0.07%
116Cs 115.933395 ± 0.000108 [Estimated] 700 ms ± 40 1975 β+=100%; β+p=0.28±0.7%; β+α=0.049±2.5%
116Csm 115.933395 ± 0.000108 [Estimated] 3.85 s ± 0.13 1975 β+=100%; β+p=0.44±0.7%; β+α=0.0034±2.3%
117Cs 116.928616723 ± 0.000067 8.4 s ± 0.6 1972 β+=100%
117Csm 116.928616723 ± 0.000067 6.5 s ± 0.4 1978 β+=100%
118Cs 117.926559517 ± 0.00001369 14 s ± 2 1969 β+=100%; β+p=0.021±1.4%; β+α=0.0012±0.5%
118Csm 117.926559517 ± 0.00001369 17 s ± 3 1972 β+=100%; β+p=0.021±1.4%; β+α=0.0012±0.5%
119Cs 118.922377327 ± 0.000014965 43.0 s ± 0.2 1969 β+=100%; β+α<2e-6%
119Csm 118.922377327 ± 0.000014965 30.4 s ± 0.1 1978 β+=100%
120Cs 119.920677277 ± 0.000010702 60.4 s ± 0.6 1969 β+=100%; β+α<2.0e-5±0.4%; β+p<7e-6±0.3%
120Csm 119.920677277 ± 0.000010702 57 s ± 6 1977 β+=100%; β+α<2.0e-5±0.4%; β+p<7e-6±0.3%
121Cs 120.917227235 ± 0.00001534 155 s ± 4 1969 β+=100%
121Csm 120.917227235 ± 0.00001534 122 s ± 3 1981 β+≈83%; IT≈17%
122Cs 121.916108144 ± 0.000036164 21.18 s ± 0.19 1969 β+=100%; β+α<2e-7%
122Csm 121.916108144 ± 0.000036164 >1 us 1987 IT=100%
122Csn 121.916108144 ± 0.000036164 3.70 m ± 0.11 1969 β+=100%
122Csp 121.916108144 ± 0.000036164 360 ms ± 20 1969 IT=100%
123Cs 122.912996060 ± 0.000013 5.88 m ± 0.03 1954 β+=100%
123Csm 122.912996060 ± 0.000013 1.64 s ± 0.12 1972 IT=100%
123Csn 122.912996060 ± 0.000013 114 ns ± 5 2000 IT=100%
124Cs 123.912247366 ± 0.000009823 30.9 s ± 0.4 1969 β+=100%
124Csm 123.912247366 ± 0.000009823 6.41 s ± 0.07 1983 IT=99.89±0.2%; β+=0.11±0.2%
125Cs 124.909725953 ± 0.000008304 44.35 m ± 0.29 1954 β+=100%
125Csm 124.909725953 ± 0.000008304 900 us ± 30 1998 IT=100%
126Cs 125.909445821 ± 0.00001112 1.64 m ± 0.02 1954 β+=100%
126Csm 125.909445821 ± 0.00001112 ~1 us 1993 IT=100%
126Csn 125.909445821 ± 0.00001112 171 us ± 14 1993 IT=100%
127Cs 126.907417527 ± 0.000005987 6.25 h ± 0.10 1950 β+=100%
127Csm 126.907417527 ± 0.000005987 55 us ± 3 1980 IT=100%
128Cs 127.907748452 ± 0.000005771 3.640 m ± 0.014 1951 β+=100%
129Cs 128.906065910 ± 0.000004888 32.06 h ± 0.06 1950 β+=100%
129Csm 128.906065910 ± 0.000004888 718 ns ± 21 1977 IT=100%
130Cs 129.906709281 ± 0.000008971 29.21 m ± 0.04 1952 β+=98.4%; β-=1.6%
130Csm 129.906709281 ± 0.000008971 3.46 m ± 0.06 1977 IT≈100%; β+=0.16±0.2%
131Cs 130.905468457 ± 0.00000019 9.689 d ± 0.016 1947 ε=100%
132Cs 131.906437740 ± 0.000001112 6.480 d ± 0.006 1953 β+=98.13±0.9%; β-=1.87±0.9%
133Cs 132.905451958 ± 0.000000008 Stable 1921 IS=100%
134Cs 133.906718501 ± 0.000000017 2.0650 y ± 0.0004 1940 β-=100%; ε=0.00030±1.2%
134Csm 133.906718501 ± 0.000000017 2.912 h ± 0.002 1975 IT=100%
135Cs 134.905976907 ± 0.00000039 1.33 My ± 0.19 1949 β-=100%
135Csm 134.905976907 ± 0.00000039 53 m ± 2 1962 IT=100%
136Cs 135.907311431 ± 0.00000201 13.01 d ± 0.05 1951 β-=100%
136Csm 135.907311431 ± 0.00000201 17.5 s ± 0.2 1981 IT=?; β- ?
137Cs 136.907089296 ± 0.000000324 30.04 y ± 0.04 1951 β-=100%
138Cs 137.911017119 ± 0.000009831 33.5 m ± 0.2 1943 β-=100%
138Csm 137.911017119 ± 0.000009831 2.91 m ± 0.10 1971 IT=81±0.3%; β-=19±0.3%
139Cs 138.913363822 ± 0.000003364 9.27 m ± 0.05 1939 β-=100%
140Cs 139.917283707 ± 0.000008801 63.7 s ± 0.3 1950 β-=100%
140Csm 139.917283707 ± 0.000008801 471 ns ± 51 1974 IT=100%
141Cs 140.920045279 ± 0.000009871 24.84 s ± 0.16 1962 β-=100%; β-n=0.0342±1.4%
142Cs 141.924299514 ± 0.000007586 1.687 s ± 0.010 1962 β-=100%; β-n=0.089±0.3%
143Cs 142.927347346 ± 0.00000813 1.802 s ± 0.008 1962 β-=100%; β-n=1.62±0.6%
144Cs 143.932075402 ± 0.000021612 994 ms ± 6 1967 β-=100%; β-n=2.98±0.6%
144Csm 143.932075402 ± 0.000021612 1.1 us ± 0.1 2009 IT=100%
144Csn 143.932075402 ± 0.000021612 <1 s 1978 β-=?; IT ?; β-n ?
145Cs 144.935528927 ± 0.000009733 582 ms ± 4 1971 β-=100%; β-n=12.8±0.3%
145Csm 144.935528927 ± 0.000009733 500 ns ± 100 2015 IT=100%
146Cs 145.940621867 ± 0.000003106 321.6 ms ± 0.9 1971 β-=100%; β-n=14.2±0.4%; β-2n ?
146Csm 145.940621867 ± 0.000003106 1.25 us ± 0.05 2015 IT=100%
147Cs 146.944261512 ± 0.000009 230.5 ms ± 0.9 1978 β-=100%; β-n=28.5±1.5%
147Csm 146.944261512 ± 0.000009 190 ns ± 20 2015 IT=100%
148Cs 147.949639026 ± 0.000014 151.8 ms ± 1.0 1978 β-=100%; β-n=28.7±2.1%; β-2n ?
148Csm 147.949639026 ± 0.000014 4.8 us ± 0.2 2015 IT=100%
149Cs 148.953516 ± 0.000429 [Estimated] 112.3 ms ± 2.5 1979 β-=100%; β-n=25±0.4%; β-2n ?
150Cs 149.959023 ± 0.000429 [Estimated] 81.0 ms ± 2.6 1979 β-=100%; β-n≈44%; β-2n ?
151Cs 150.963199 ± 0.000537 [Estimated] 59 ms ± 19 1979 β-=100%; β-n ?; β-2n ?
152Cs 151.968728 ± 0.000537 [Estimated] 17 ms [Estimated] 1987 β- ?; β-n ?

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
    Cesium

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