26
Fe
Iron
Atomic Mass 55.845
Electron Configuration [Ar]4s23d6
Oxidation States +3, +2
Year Discovered Ancient

Identifiers

Element Name Iron
Element Symbol Fe
InChI InChI=1S/Fe
InChIKey XEEYBQQBJWHFJM-UHFFFAOYSA-N

Properties

Atomic Weight

55.845(2)

55.845

55.85

55.845(2)

Electron Configuration

[Ar]4s23d6

Atomic Radius

Van der Waals Atomic Radius : 194 pm (Van der Waals)

Empirical Atomic Radius : 140pm (Empirical)

Covalent Atomic Radius : 132(3)[l.s.], 152(6)[h.s.] pm (Covalent)

Oxidation States

+3, +2

-4, -2, -1, +1,+2, +3, +4, +5,+6, +7 ​(an amphoteric oxide)

Ground Level

5D4

Ionization Energy

7.902 eV

7.9024681 ± 0.0000012 eV

Electronegativity

Pauling Scale Electronegativity : 1.83(Pauling Scale)

Allen Scale Electronegativity : 1.8(Allen Scale)

Electron Affinity

0.163eV

0.46eV

Atomic Spectra

Lines Holdings

Levels Holdings

Physical Description

Solid

Element Classification

Metal

Element Period Number

4

Element Group Number

8

Density

7.874 grams per cubic centimeter

Melting Point

1811 K (1538°C or 2800°F)

1538°C

Boiling Point

3134 K (2861°C or 5182°F)

2862°C

Estimated Crustal Abundance

5.63×104 milligrams per kilogram

Estimated Oceanic Abundance

2×10-3 milligrams per liter

History

The name derives from the Anglo-Saxon iron of unknown origin. The element has been known from prehistoric times. The symbol Fe is derived from the Latin ferrum for "firmness". It is of interest to note that 56Fe requires more energy to be formed than any other nuclide. It is, therefore, the ultimate endproduct of stellar nuclear fusion.

Archaeological evidence suggests that people have been using iron for at least 5000 years. Iron is the cheapest and one of the most abundant of all metals, comprising nearly 5.6% of the earth's crust and nearly all of the earth's core. Iron is primarily obtained from the minerals hematite (Fe2O3) and magnetite (Fe3O4). The minerals taconite, limonite (FeO(OH)·nH2O) and siderite (FeCO3) are other important sources.

Latin ferrum. Iron was used prehistorically:

▸ Iron is mentioned numerous times in the Old Testament of the Bible.

▸ A remarkable iron pillar, dating to about A.D. 400, remains standing today in Delhi, India. This solid shaft of wrought iron is about 7 1/4 m high by 40 cm in diameter. Corrosion to the pillar has been minimal although it has been exposed to the weather since its creation.

Historical Atomic Weights

Year Atomic Weight (uncertainty) [u] Reference
1993 55.845(2) https://doi.org/10.1351/pac199466122423
1961 55.847(3) https://doi.org/10.1021/ja00881a001
1940 55.85 https://doi.org/10.1039/JR9400000475
1912 55.84 https://doi.org/10.1021/ja02224a601
1909 55.85 https://doi.org/10.1021/ja01931a001
1902 55.9 https://doi.org/10.1007/BF01370337

Historical Isotopic Abundances

Year Isotope Abundance (uncertainty) Reference
2013 54Fe 0.058 45(105) https://doi.org/10.1515/pac-2015-0503
2013 56Fe 0.917 54(106) https://doi.org/10.1515/pac-2015-0503
2013 57Fe 0.021 19(29) https://doi.org/10.1515/pac-2015-0503
2013 58Fe 0.002 82(12) https://doi.org/10.1515/pac-2015-0503
1997 54Fe 0.058 45(35) https://doi.org/10.1351/pac199870010217
1997 56Fe 0.917 54(36) https://doi.org/10.1351/pac199870010217
1997 57Fe 0.021 19(10) https://doi.org/10.1351/pac199870010217
1997 58Fe 0.002 82(4) https://doi.org/10.1351/pac199870010217
1981 54Fe 0.058(1) https://doi.org/10.1351/pac198355071119
1981 56Fe 0.9172(30) https://doi.org/10.1351/pac198355071119
1981 57Fe 0.022(1) https://doi.org/10.1351/pac198355071119
1981 58Fe 0.0028(1) https://doi.org/10.1351/pac198355071119
1979 54Fe 0.058(1) https://doi.org/10.1351/pac198052102349
1979 56Fe 0.917(3) https://doi.org/10.1351/pac198052102349
1979 57Fe 0.022(1) https://doi.org/10.1351/pac198052102349
1979 58Fe 0.003(1) https://doi.org/10.1351/pac198052102349
1975 54Fe 0.058 https://doi.org/10.1351/pac197647010075
1975 56Fe 0.918 https://doi.org/10.1351/pac197647010075
1975 57Fe 0.021 https://doi.org/10.1351/pac197647010075
1975 58Fe 0.003 https://doi.org/10.1351/pac197647010075

Description

The pure metal is very reactive chemically and rapidly corrodes, especially in moist air or at elevated temperatures. It has four allotropic forms or ferrites, known as alpha, beta, gamma, and omega, with transition points at 700, 928, and 1530C. The alpha form is magnetic, but when transformed into the beta form, the magnetism disappears although the lattice remains unchanged. The relations of these forms are peculiar. Pig iron is an alloy containing about 3 percent carbon with varying amounts of sulfur, silicon, manganese, and phosphorus.

Iron is hard, brittle, fairly fusible, and is used to produce other alloys, including steel. Wrought iron contains only a few tenths of a percent of carbon, is tough, malleable, less fusible, and usually has a "fibrous" structure.

Carbon steel is an alloy of iron with small amounts of Mn, S, P, and Si. Alloy steels are carbon steels with other additives such as nickel, chromium, vanadium, etc. Iron is a cheap, abundant, useful, and important metal.

Users

Huge amounts of iron are used to make steel, an alloy of iron and carbon. Steel typically contains between 0.3% and 1.5% carbon, depending on the desired characteristics. The addition of other elements can give steel other useful properties. Small amounts of chromium improves durability and prevents rust (stainless steel); nickel increases durability and resistance to heat and acids; manganese increases strength and resistance to wear; molybdenum increases strength and resistance to heat; tungsten retains hardness at high temperatures; and vanadium increases strength and springiness. Steel is used to make paper clips, skyscrapers and everything in between.

In addition to helping build the world around us, iron helps keep plants and animals alive. Iron plays a role in the creation of chlorophyll in plants and is an essential part of hemoglobin, the substance that carries oxygen within red blood cells. Iron sulfate (FeSO4) is used to treat the blood disease anemia.

Iron is a vital constituent of plant and animal life and works as an oxygen carrier in hemoglobin.

Taconite is becoming increasingly important as a commercial ore. The pure metal is not often encountered in commerce, but is usually alloyed with carbon or other metals.

Sources

Iron is a relatively abundant element in the universe. It is found in the sun and many types of stars in considerable quantity. Its nuclei are very stable. Iron is a principal component of a meteorite class known as siderites and is a minor constituent of the other two meteorite classes. The core of the earth 2150 miles in radius is thought to be largely composed of iron with about 10 percent occluded hydrogen. The metal is the fourth most abundant element, by weight that makes up the crust of the earth.

The most common ore is hematite, which is frequently seen as black sands along beaches and banks of streams.

Compounds

See more information at the Iron compound page.

Element Forms

CID Name Formula SMILES Molecular Weight
23925 iron Fe [Fe] 55.84
27284 iron(2+) Fe+2 [Fe+2] 55.84
29936 iron(3+) Fe+3 [Fe+3] 55.84
10313045 iron-56 Fe [56Fe] 55.934936
26815 iron-55 Fe [55Fe] 54.938291
104784 iron-59 Fe [59Fe] 58.934873
167161 iron-57 Fe [57Fe] 56.935392
169394 iron-60 Fe [60Fe] 59.93407
185123 iron-55(3+) Fe+3 [55Fe+3] 54.938291
10197609 iron-52 Fe [52Fe] 51.948113
11963629 iron(4+) Fe+4 [Fe+4] 55.84
11963693 iron(6+) Fe+6 [Fe+6] 55.84
11963738 iron(5+) Fe+5 [Fe+5] 55.84
25087137 iron-58 Fe [58Fe] 57.933274
44146792 iron-54 Fe [54Fe] 53.939608
177060 iron-59(3+) Fe+3 [59Fe+3] 58.934873
71587104 iron-57(2+) Fe+2 [57Fe+2] 56.935392
25087149 iron-51 Fe [51Fe] 50.95686
66561989 iron-55(2+) Fe+2 [55Fe+2] 54.938291
73952216 iron-59(2+) Fe+2 [59Fe+2] 58.934873
76964293 iron-52(3+) Fe+3 [52Fe+3] 51.948113
76968747 iron-58(2+) Fe+2 [58Fe+2] 57.933274

Isotopes

Stable Isotope Count 4
Summary Common iron is a mixture of four isotopes. Ten other isotopes are known to exist.

Isotopes in Biology

Natural iron enriched in its least abundant stable isotopes, 57Fe and 58Fe, are used as a tracer in human studies to assess absorption, excretion, distribution, and utilization of iron in basic and applied research [108], [109], [110], [214], [215], [216]. The two radioisotopes, 55Fe and 59Fe, have sufficiently long half-lives of 2.75 years and 44.5 days, respectively, to be used as tracers, but potential health and environmental hazards limit their use to diagnostic applications in patient care (i.e. disorders of blood and of iron metabolism) [110], [215], [216].

[108] World Nuclear Association. Radioisotopes in Industry: Industrial Uses of Radioisotopes, World Nuclear Association (2014), Feb. 24; http://www.world-nuclear.org/info/inf56.html.
[109] Australian Government, Australian Nuclear Science and Technology Organisation (Ansto). [Radioisotopes]:/their Role in Society Today/, Australian Government, Australian Nuclear Science and Technology Organisation (Ansto) (2014), Feb. 24; http://www.ansto.gov.au/__data/assets/pdf_file/0018/3564/Radioisotopes.pdf.
[110] AUS-e-TUTE for Astute Science Students. Chemistry Tutorial: Summary of Radioactive Particles, Isotopes, Properties and Uses, AUS-e-TUTE for Astute Science Students (2014), Feb. 24; http://www.ausetute.com.au/nuclesum.html.
[214] Z. Chen, I. J. Griffin, L. M. Plumlee, S. A. Abrams. J. Nutr.135, 1790 (2005).
[215] S. A. Abrams. Am. J. Clin. Nutr.70, 955 (1999).
[216] N. Dauphas, O. Rouxel. Mass Spectrom. Rev.25, 515 (2006).

Isotopes in Earth/Planetary Science

60Fe is an extinct radionuclide with a half-life of 2.6×106 years that has fully decayed to 60Ni since formation of the Solar System. The distribution of the product (radiogenic) 60Ni in extraterrestrial material, such as meteorites, has been used to gain insight into the early history of the Solar System [216]. Because molecules, atoms, and ions of the stable isotopes of iron possess slightly different physical and chemical properties, they commonly will be fractionated during physical, chemical, and biological processes, giving rise to variations in isotopic abundances and in atomic weights. There are measureable variations in the isotopic abundances of iron in natural terrestrial materials (Fig. IUPAC.26.1). Small variations in stable iron isotopic compositions caused by physical and chemical isotopic fractionation processes have been used to study mass transfer processes in nature and chemical equilibria [17], [216], [217].

Fig. IUPAC.26.1: Variation in atomic weight with isotopic composition of selected iron-bearing materials (modified from [17]).

[17] T. B. Coplen, J. A. Hopple, J. K. Böhlke, H. S. Peiser, S. E. Rieder, H. R. Krouse, K. J. R. Rosman, T. Ding, R. D. Vocke, K. Revesz, A. Lamberty, P. D. P. Taylor, P. D. Bièvre. United States Geological Survey Water-Resources Investigations Report, 01-4222, (2002).
[216] N. Dauphas, O. Rouxel. Mass Spectrom. Rev.25, 515 (2006).
[217] United States Geological Survey. Resources on Isotopes-Periodic Table-Iron, United States Geological Survey (2014), Feb. 25; http://wwwrcamnl.wr.usgs.gov/isoig/period/fe_iig.html.

Isotopes in Industry

55Fe is a beta emitting nuclide that serves as an electron source together with 63Ni (with a half-life of 99 years) in electron-capture detectors. Electron-capture detectors are used as thickness gauges or as detectors for organic analytes in gas chromatography [218].

[218] P. Cassettea, T. Altzitzogloub, R. Brodac, R. Colléd, P. Dryake, P. de Felicef, E. Guntherg, J. M. Los Arcosh, G. Rateli, B. Simpsonj, F. Verrezen. Appl. Radiat. Isot.49, 1403 (1998).

Isotopes in Medicine

52Fe, with a half-life of 8.3 h, emits positrons and is used in positron emission tomography (PET) studies. It can be produced in a cyclotron from stable 50Cr by alpha particle capture [99], [219], [220].

[99] World Nuclear Association. Radioisotopes in Medicine, World Nuclear Association (2014), Feb. 23; http://www.world-nuclear.org/info/inf55.html.
[219] M. Bruehlmeier, K. L. Leenders, P. Vontobel, C. Calonder, A. Antonini, A. Weindl. J. Nucl. Med.41, 781 (2000).
[220] A. Agool, A. W. Glaudemans, H. H. Boersma, R. A. Dierckx, E. Vellenga, R. H. Slart. Eur. J. Nucl. Med. Mol. Imaging38, 166 (2011).

Isotopes Used as a Source of Radioactive Isotope(s)

Stable 56Fe is used for production of radioactive 55Co (with a half-life of about 18 h), as an emitter of positrons for PET applications using the reaction 56Fe (p, 2n) 55Co [221], [222].

[221] S. Spellerberg, P. Reimer, G. Blessing, H. H. Coenen, S. M. Qaim. Appl. Radiat. Isot.49, 1519 (1998).
[222] F. Haddad, L. Ferrer, A. Guertin, T. Carlier, N. Michel, J. Barbet, J. F. Chatal. Eur. J. Nucl. Med. Mol. Imaging35, 1377 (2008).

Isotope Mass and Abundance

Isotope Atomic Mass (uncertainty) [u] Abundance (uncertainty)
54Fe 53.939 608(3) 0.058 45(105)
56Fe 55.934 936(2) 0.917 54(106)
57Fe 56.935 392(2) 0.021 19(29)
58Fe 57.933 274(3) 0.002 82(12)
Isotope Atomic Mass (uncertainty) [u] Abundance (uncertainty)
54Fe 53.93960899(53) 0.05845(35)
56Fe 55.93493633(49) 0.91754(36)
57Fe 56.93539284(49) 0.02119(10)
58Fe 57.93327443(53) 0.00282(4)

Atomic Mass, Half Life, and Decay

Nuclide Atomic Mass and Uncertainty [u] Half Life and Uncertainty Discovery Year Decay Modes, Intensities and Uncertainties [%]
45Fe 45.015467 ± 0.000304 [Estimated] 2.5 ms ± 0.2 1996 2p=70±0.4%; β+=30±0.4%; β+p=18.9±3.5%; β+2p=7.8±2.3%
46Fe 46.001299 ± 0.000322 [Estimated] 13.0 ms ± 2.0 1992 β+=100%; β+p=78.7±3.8%; β+2p=?
47Fe 46.992346 ± 0.000537 [Estimated] 21.9 ms ± 0.2 1992 β+=100%; β+p=88.4±0.9%
47Fem 46.992346 ± 0.000537 [Estimated] Not-specified IT ?
48Fe 47.980667000 ± 0.000099 45.3 ms ± 0.6 1987 β+=100%; β+p=15.3±0.5%
49Fe 48.973429000 ± 0.000026 64.7 ms ± 0.3 1970 β+=100%; β+p=56.7±0.4%
50Fe 49.962988000 ± 0.000009 152.0 ms ± 0.6 1977 β+=100%; β+p≈0%
51Fe 50.956855137 ± 0.000001501 305.4 ms ± 2.3 1972 β+=100%
52Fe 51.948113364 ± 0.000000192 8.275 h ± 0.008 1948 β+=100%
52Fem 51.948113364 ± 0.000000192 45.9 s ± 0.6 1979 β+=99.979±0.5%; IT=0.021±0.5%
53Fe 52.945305629 ± 0.000001792 8.51 m ± 0.02 1938 β+=100%
53Fem 52.945305629 ± 0.000001792 2.54 m ± 0.02 1967 IT=100%
54Fe 53.939608189 ± 0.000000368 Stable 1923 IS=5.845±10.5%; 2β+ ?
54Fem 53.939608189 ± 0.000000368 364 ns ± 7 1983 IT=100%
55Fe 54.938291158 ± 0.00000033 2.7562 y ± 0.0004 1939 ε=100%
56Fe 55.934935537 ± 0.000000287 Stable 1923 IS=91.754±10.6%
57Fe 56.935391950 ± 0.000000287 Stable 1935 IS=2.119±2.9%
58Fe 57.933273575 ± 0.000000339 Stable 1935 IS=0.282±1.2%
59Fe 58.934873492 ± 0.000000354 44.500 d ± 0.012 1938 β-=100%
60Fe 59.934070249 ± 0.000003656 2.62 My ± 0.04 1957 β-=100%
61Fe 60.936746241 ± 0.0000028 5.98 m ± 0.06 1957 β-=100%
61Fem 60.936746241 ± 0.0000028 238 ns ± 5 1998 IT=100%
62Fe 61.936791809 ± 0.000003 68 s ± 2 1975 β-=100%
63Fe 62.940272698 ± 0.000004618 6.1 s ± 0.6 1980 β-=100%
64Fe 63.940987761 ± 0.000005386 2.0 s ± 0.2 1980 β-=100%
65Fe 64.945015323 ± 0.000005487 805 ms ± 10 1980 β-=100%; β-n ?
65Fem 64.945015323 ± 0.000005487 1.12 s ± 0.15 2008 β- ?
65Fen 64.945015323 ± 0.000005487 418 ns ± 12 1998 IT=100%
66Fe 65.946249958 ± 0.0000044 467 ms ± 29 1985 β-=100%; β-n ?
67Fe 66.950930000 ± 0.0000041 394 ms ± 9 1985 β-=100%; β-n ?
67Fem 66.950930000 ± 0.0000041 64 us ± 17 1998 IT=100%
67Fen 66.950930000 ± 0.0000041 75 us ± 21 2008 IT=100%
68Fe 67.952875 ± 0.000207 [Estimated] 188 ms ± 4 1985 β-=100%; β-n>0%
69Fe 68.957918 ± 0.000215 [Estimated] 162 ms ± 7 1992 β-=100%; β-n ?; β-2n ?
70Fe 69.960397 ± 0.000322 [Estimated] 61.4 ms ± 0.7 1997 β-=100%; β-n ?
71Fe 70.965722 ± 0.000429 [Estimated] 34.3 ms ± 2.6 1997 β-=100%; β-n ?; β-2n ?
72Fe 71.968599 ± 0.000537 [Estimated] 17.0 ms ± 1.0 1997 β-=100%; β-n ?; β-2n ?
73Fe 72.974246 ± 0.000537 [Estimated] 12.9 ms ± 1.6 2010 β-=100%; β-n ?; β-2n ?
74Fe 73.977821 ± 0.000537 [Estimated] 5 ms ± 5 2010 β-=100%; β-n ?; β-2n ?
75Fe 74.984219 ± 0.000644 [Estimated] 9 ms >620ns [Estimated] 2013 β- ?; β-n ?; β-2n ?
76Fe 75.988631 ± 0.000644 [Estimated] 3 ms >410ns [Estimated] 2017 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
    Iron

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