60
Nd
Neodymium
Atomic Mass 144.242
Electron Configuration [Xe]6s24f4
Oxidation States +3
Year Discovered 1885

Identifiers

Element Name Neodymium
Element Symbol Nd
InChI InChI=1S/Nd
InChIKey QEFYFXOXNSNQGX-UHFFFAOYSA-N

Properties

Atomic Weight

144.242(3)

144.242

144.2

144.242(3)

Electron Configuration

[Xe]6s24f4

Atomic Radius

Van der Waals Atomic Radius : 229 pm (Van der Waals)

Empirical Atomic Radius : 185pm (Empirical)

Covalent Atomic Radius : 201(6) pm (Covalent)

Oxidation States

+3

+4, +3, +2 ​(a mildly basic oxide)

Ground Level

5I4

Ionization Energy

5.525 eV

5.52475 ± 0.00005 eV

Electronegativity

Pauling Scale Electronegativity : 1.14(Pauling Scale)

Atomic Spectra

Lines Holdings

Levels Holdings

Physical Description

Solid

Element Classification

Metal

Element Period Number

6

Element Group Number

- Lanthanide

Density

7.01 grams per cubic centimeter

Melting Point

1294 K (1021°C or 1870°F)

1024°C

Boiling Point

3347 K (3074°C or 5565°F)

3074°C

Estimated Crustal Abundance

4.15×101 milligrams per kilogram

Estimated Oceanic Abundance

2.8×10-6 milligrams per liter

History

The name derives from the Greek neos for "new" and didymos for "twin". It was discovered by the Swedish surgeon and chemist Carl Gustav Mosander in 1841, who called it didymium (or twin) because of its similarity to lanthanum, which he had previously discovered two years earlier. In 1885, the Austrian chemist Carl Auer (Baron von Welsbach) separated didymium into two elements, one of which he called neodymium (or new twin).

Neodymium was discovered by Carl F. Auer von Welsbach, an Austrian chemist, in 1885. He separated neodymium, as well as the element praseodymium, from a material known as didymium. Today, neodymium is primarily obtained from through an ion exchange process monazite sand ((Ce, La, Th, Nd, Y)PO4), a material rich in rare earth elements.

From the Greek word neos meaning new, and didymos, twin. In 1841, Mosander, extracted a rose-colored oxide from cerite , which he believed contained a new element. He named the element didymium, as it was an inseparable twin brother of lanthanum. In 1885 von Welsbach separated didymium into two new elemental components, neodymia and praseodymia, by repeated fractionation of ammonium didymium nitrate. While the free metal is in misch metal, long known and used as a pyrophoric alloy for light flints, the element was not isolated in relatively pure form until 1925. Neodymium is present in misch metal to the extent of about 18%. It is present in the minerals monazite and bastnasite, which are principal sources of rare-earth metals.

Historical Atomic Weights

Year Atomic Weight (uncertainty) [u] Reference
2005 144.242(3) https://doi.org/10.1351/pac200678112051
1969 144.24(3) https://doi.org/10.1351/pac197021010091
1961 144.24 https://doi.org/10.1021/ja00881a001
1925 144.27 https://doi.org/10.1039/CT9252700913
1909 144.3 https://doi.org/10.1021/ja01931a001
1902 143.6 https://doi.org/10.1007/BF01370337

Historical Isotopic Abundances

Year Isotope Abundance (uncertainty) Reference
2009 142Nd 0.271 52(40) https://doi.org/10.1351/PAC-REP-10-06-02
2009 143Nd 0.121 74(26) https://doi.org/10.1351/PAC-REP-10-06-02
2009 144Nd 0.237 98(19) https://doi.org/10.1351/PAC-REP-10-06-02
2009 145Nd 0.082 93(12) https://doi.org/10.1351/PAC-REP-10-06-02
2009 146Nd 0.171 89(32) https://doi.org/10.1351/PAC-REP-10-06-02
2009 148Nd 0.057 56(21) https://doi.org/10.1351/PAC-REP-10-06-02
2009 150Nd 0.056 38(28) https://doi.org/10.1351/PAC-REP-10-06-02
1997 142Nd 0.272(5) https://doi.org/10.1351/pac199870010217
1997 143Nd 0.122(2) https://doi.org/10.1351/pac199870010217
1997 144Nd 0.238(3) https://doi.org/10.1351/pac199870010217
1997 145Nd 0.083(1) https://doi.org/10.1351/pac199870010217
1997 146Nd 0.172(3) https://doi.org/10.1351/pac199870010217
1997 148Nd 0.057(1) https://doi.org/10.1351/pac199870010217
1997 150Nd 0.056(2) https://doi.org/10.1351/pac199870010217
1989 142Nd 0.2713(12) https://doi.org/10.1351/pac199163070991
1989 143Nd 0.1218(6) https://doi.org/10.1351/pac199163070991
1989 144Nd 0.2380(12) https://doi.org/10.1351/pac199163070991
1989 145Nd 0.0830(6) https://doi.org/10.1351/pac199163070991
1989 146Nd 0.1719(9) https://doi.org/10.1351/pac199163070991
1989 148Nd 0.0576(3) https://doi.org/10.1351/pac199163070991
1989 150Nd 0.0564(3) https://doi.org/10.1351/pac199163070991
1979 142Nd 0.2716(7) https://doi.org/10.1351/pac198052102349
1979 143Nd 0.1218(3) https://doi.org/10.1351/pac198052102349
1979 144Nd 0.2380(7) https://doi.org/10.1351/pac198052102349
1979 145Nd 0.0829(2) https://doi.org/10.1351/pac198052102349
1979 146Nd 0.1719(3) https://doi.org/10.1351/pac198052102349
1979 148Nd 0.0575(2) https://doi.org/10.1351/pac198052102349
1979 150Nd 0.0563(2) https://doi.org/10.1351/pac198052102349
1975 142Nd 0.272 https://doi.org/10.1351/pac197647010075
1975 143Nd 0.122 https://doi.org/10.1351/pac197647010075
1975 144Nd 0.238 https://doi.org/10.1351/pac197647010075
1975 145Nd 0.083 https://doi.org/10.1351/pac197647010075
1975 146Nd 0.172 https://doi.org/10.1351/pac197647010075
1975 148Nd 0.057 https://doi.org/10.1351/pac197647010075
1975 150Nd 0.056 https://doi.org/10.1351/pac197647010075

Description

The metal has a bright silvery metallic luster, Neodymium is one of the more reactive rare-earth metals and quickly tarnishes in air, forming an oxide that spalls off and exposes metal to oxidation. The metal, therefore, should be kept under light mineral oil or sealed in a plastic material. Neodymium exists in two allotropic forms, with a transformation from a double hexagonal to a body-centered cubic structure taking place at 863°C.

Users

Neodymium makes up about 18% of Misch metal, a material that is used to make flints for lighters. Neodymium is also a component of didymium glass, which is used to make certain types of welder's and glass blower's goggles. Neodymium is added to glass to remove the green color caused by iron contaminants. It can also be added to glass to create violet, red or gray colors. Some types of glass containing neodymium are used by astronomers to calibrate devices called spectrometers and other types are used to create artificial rubies for lasers. Some neodymium salts are used to color enamels and glazes.

Didymium, of which neodymium is a component, is used for coloring glass to make welders goggles. By itself, neodymium colors glass delicate shades ranging from pure violet through wine-red and warm gray. Light transmitted through such glass shows unusually sharp absorption bands. The glass has been used in astronomical work to produce sharp bands by which spectral lines may be calibrated. Glass containing neodymium can be used as a laser material to produce coherent light. Neodymium salts are also used as a colorant for enamels.

Compounds

See more information at the Neodymium compound page.

Element Forms

CID Name Formula SMILES Molecular Weight
23934 neodymium Nd [Nd] 144.24
3788361 neodymium(3+) Nd+3 [Nd+3] 144.24
114848 neodymium-147 Nd [147Nd] 146.91611
25087164 neodymium-143 Nd [143Nd] 142.90982
71586741 neodymium-142 Nd [142Nd] 141.90773
177666 neodymium-149 Nd [149Nd] 148.92015
177494 neodymium-141 Nd [141Nd] 140.90962
177598 neodymium-146 Nd [146Nd] 145.91312
177623 neodymium-138 Nd [138Nd] 137.9120
25087165 neodymium-145 Nd [145Nd] 144.91258
44152648 neodymium-148 Nd [148Nd] 147.91690
176415 neodymium-136 Nd [136Nd] 135.9150
176987 neodymium-139 Nd [139Nd] 138.9120
177620 neodymium-151 Nd [151Nd] 150.92384
131708399 neodymium-144 Nd [144Nd] 143.91009
131708400 neodymium-150 Nd [150Nd] 149.92090

Handling And Storage

Neodymium has a low-to-moderate acute toxic rating. As with other rare earths, neodymium should be handled with care.

Isotopes

Stable Isotope Count 5
Summary Natural neodymium is a mixture of seven stable isotopes. Fourteen other radioactive isotopes are recognized.

Isotopes in Geochronology

143Nd is a radiogenic isotope produced by decay of 147Sm, with a half-life of 1.06×1011 years. Thus, the isotope-amount ratio n(143Nd)/n(144Nd) can be used for dating rocks on long time scales and as a chemical tracer in geochemistry (Fig. IUPAC.60.1) [427], [428]. The very small accumulation of 142Nd in billion-year-old metamorphosed rocks from Greenland [from the relatively short-lived (about 68×106 years) alpha decay of 146Sm] provided evidence that the crust of the Earth formed before the young planet was more than 100×106 years old. This is because only a short amount of time could have elapse to incorporate the 146Sm parent radionuclide into the ancient Greenland minerals before it decayed [429], [430].

Fig. IUPAC.60.1: Cross plot of n(¹⁴³Nd)/n(¹⁴⁴Nd) isotope-amount ratio and n(¹⁴⁷Sm)/n(¹⁴⁴Nd) amount ratio for two periods of scheelite (calcium tungstate; ore of tungsten) mineralization (metamorphism) (modified from [428]). ¹⁴³Nd is produced by decay of ¹⁴⁷Sm. Rock containing higher amounts of ¹⁴⁷Sm at time of mineralization will over time produce higher amounts of ¹⁴³Nd (e.g. sample stage 3 K1 shear zone and sample stage 4 K2). Alternatively, rocks containing lower amounts of ¹⁴⁷Sm at time of mineralization will over time produce lower amounts of ¹⁴³Nd (e.g. sample stage 3 K1 gneiss and sample Brl). Samples from an older mineralization event will have proportionally more ¹⁴³Nd because of the longer accumulation time for ¹⁴³Nd; thus, the line through the bluish-fluorescent scheelites with an age of (319 ± 34)×10⁶ a has a substantially higher slope than the line through the whitish-bluish-fluorescent scheelites with an age of (29 ± 17)×10⁶ a. These lines from which age of mineralization (crystallization) can be determined are called isochrons.

[427] M. T. McCullocha, M. R. Perfita. Earth. Planet. Sci. Lett.56, 167 (1981).
[428] R. Eichhorn, R. Höll, E. Jagoutz, U. Schärer. Geochim. Cosmochim. Acta61, 5005 (1997).
[429] M. G. Jackson, S. R. Hart, A. A. P. Koppers, H. Staudigel, J. Konter, J. Blusztajn, M. Kurz, J. A. Russell. Nature448, 684 (2007).
[430] G. Caro, B. Bourdon, J. L. Birck, S. Moorbath. Nature423, 428 (2003).

Isotopes Used as a Source of Radioactive Isotope(s)

146Nd has been used in the production of 147Pm (with a half-life of 2.6 years), via the reaction 146Nd (n, γ) 147Nd, which is followed by a subsequent electron decay reaction, 147Nd→ 147Pm+β - reaction. 147Pm is a radioactive power-generation source [431].

[431] C. S. Lee, Y. M. Wang, W. L. Cheng, G. Ting. J. Radioanal. Nucl. Chem.130, 21 (1988).

Isotope Mass and Abundance

Isotope Atomic Mass (uncertainty) [u] Abundance (uncertainty)
142Nd 141.907 73(1) 0.271 52(40) 0.27152(40)
143Nd 142.909 82(1) 0.121 74(26) 0.12174(26)
144Nd 143.910 09(1) 0.237 98(19) 0.23798(19)
145Nd 144.912 58(1) 0.082 93(12) 0.08293(12)
146Nd 145.913 12(1) 0.171 89(32) 0.17189(32)
148Nd 147.916 90(2) 0.057 56(21) 0.05756(21)
150Nd 149.920 902(9) 0.056 38(28) 0.05638(28)

Atomic Mass, Half Life, and Decay

Nuclide Atomic Mass and Uncertainty [u] Half Life and Uncertainty Discovery Year Decay Modes, Intensities and Uncertainties [%]
124Nd 123.951873 ± 0.000537 [Estimated] 500 ms [Estimated] β+ ?; β+p ?
125Nd 124.948395 ± 0.000429 [Estimated] 650 ms ± 150 1999 β+=100%; β+p>0%
126Nd 125.942694 ± 0.000322 [Estimated] 1 s >200ns [Estimated] 2000 β+ ?; β+p ?
127Nd 126.939978 ± 0.000322 [Estimated] 1.8 s ± 0.4 1983 β+=100%; β+p=?
128Nd 127.935018 ± 0.000215 [Estimated] 5 s [Estimated] 1985 β+ ?
129Nd 128.933038 ± 0.000217 [Estimated] 6.8 s ± 0.6 1977 β+=100%; β+p=?
129Ndm 128.933038 ± 0.000217 [Estimated] 2.6 s ± 0.4 2010 β+=100%; β+p=?
130Nd 129.928506000 ± 0.00003 21 s ± 3 1977 β+=100%
131Nd 130.927248020 ± 0.000029541 25.4 s ± 0.9 1977 β+=100%; β+p=?
132Nd 131.923321237 ± 0.000025985 1.56 m ± 0.10 1977 β+=100%
133Nd 132.922348000 ± 0.00005 70 s ± 10 1977 β+=100%
133Ndm 132.922348000 ± 0.00005 ~70 s 1993 β+=?; IT=?
133Ndn 132.922348000 ± 0.00005 301 ns ± 18 1993 IT=100%
134Nd 133.918790207 ± 0.000012686 8.5 m ± 1.5 1970 β+=100%
134Ndm 133.918790207 ± 0.000012686 389 us ± 17 1969 IT=100%
135Nd 134.918181318 ± 0.000020534 12.4 m ± 0.6 1970 β+=100%
135Ndm 134.918181318 ± 0.000020534 5.5 m ± 0.5 1970 β+≈100%; IT ?
136Nd 135.914976061 ± 0.000012686 50.65 m ± 0.33 1968 β+=100%
137Nd 136.914563099 ± 0.000012586 38.5 m ± 1.5 1970 β+=100%
137Ndm 136.914563099 ± 0.000012586 1.60 s ± 0.15 1970 IT=100%
138Nd 137.911950938 ± 0.000012456 5.04 h ± 0.09 1965 β+=100%
138Ndm 137.911950938 ± 0.000012456 370 ns ± 5 1975 IT=100%
139Nd 138.911951208 ± 0.000029545 29.7 m ± 0.5 1951 β+=100%
139Ndm 138.911951208 ± 0.000029545 5.50 h ± 0.20 1951 β+=87.0±1%; IT=13.0±1%
139Ndn 138.911951208 ± 0.000029545 276.8 ns ± 1.8 1980 IT=100%
140Nd 139.909546130 ± 0.0000035 3.37 d ± 0.02 1949 ε=100%
140Ndm 139.909546130 ± 0.0000035 600 us ± 50 1962 IT=100%
140Ndn 139.909546130 ± 0.0000035 1.22 us ± 0.06 2008 IT=100%
141Nd 140.909616690 ± 0.000003417 2.49 h ± 0.03 1949 β+=100%; ε=97.28±1.6%; e+=2.72±1.6%
141Ndm 140.909616690 ± 0.000003417 62.0 s ± 0.8 1960 IT≈100%; β+=0.032±0.8%
142Nd 141.907728824 ± 0.000001348 Stable 1924 IS=27.153±4%
142Ndm 141.907728824 ± 0.000001348 16.5 us 1964 IT=100%
143Nd 142.909819815 ± 0.000001347 Stable >3.1Ey 1933 IS=12.173±2.6%
144Nd 143.910092798 ± 0.000001346 2.29 Py ± 0.16 1924 IS=23.798±1.9%; α=100%
145Nd 144.912579151 ± 0.000001364 Stable >60Py 1933 IS=8.293±1.2%; α ?
146Nd 145.913122459 ± 0.000001366 Stable >1.6Ey 1924 IS=17.189±3.2%; 2β- ?; α ?
147Nd 146.916105969 ± 0.000001368 10.98 d ± 0.01 1947 β-=100%
148Nd 147.916899027 ± 0.000002203 Stable >3.0Ey 1937 IS=5.756±2.1%; 2β- ?; α ?
149Nd 148.920154583 ± 0.000002205 1.728 h ± 0.001 1938 β-=100%
150Nd 149.920901322 ± 0.000001211 9.3 Ey ± 0.7 1937 IS=5.638±2.8%; 2β-=100%
151Nd 150.923839363 ± 0.000001215 12.44 m ± 0.07 1938 β-=100%
152Nd 151.924691242 ± 0.000026276 11.4 m ± 0.2 1969 β-=100%
153Nd 152.927717868 ± 0.000002949 31.6 s ± 1.0 1987 β-=100%
153Ndm 152.927717868 ± 0.000002949 1.10 us ± 0.04 1996 IT=100%
154Nd 153.929597404 ± 0.0000011 25.9 s ± 0.2 1970 β-=100%
154Ndm 153.929597404 ± 0.0000011 3.2 us ± 0.3 1970 IT=100%
155Nd 154.933135598 ± 0.000009826 8.9 s ± 0.2 1986 β-=100%
156Nd 155.935370358 ± 0.0000014 5.06 s ± 0.13 1987 β-=100%
156Ndm 155.935370358 ± 0.0000014 365 ns ± 145 1998 IT=100%
157Nd 156.939351074 ± 0.000002294 1.15 s ± 0.03 1992 β-=100%
158Nd 157.942205620 ± 0.0000014 810 ms ± 30 1992 β-=100%
158Ndm 157.942205620 ± 0.0000014 339 ns ± 20 2016 IT=100%
159Nd 158.946619085 ± 0.000032 500 ms ± 30 2012 β-=100%; β-n ?
160Nd 159.949839172 ± 0.00005 439 ms ± 37 1985 β-=100%; β-n ?
160Ndm 159.949839172 ± 0.00005 1.63 us ± 0.21 2016 IT=100%
161Nd 160.954664 ± 0.000429 [Estimated] 215 ms ± 76 2012 β-=100%; β-n ?
162Nd 161.958121 ± 0.000429 [Estimated] 310 ms ± 200 2012 β-=100%
163Nd 162.963414 ± 0.000537 [Estimated] 80 ms >550ns [Estimated] 2018 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
    Neodymium

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