64
Gd
Gadolinium
Atomic Mass 157.25
Electron Configuration [Xe]6s24f75d1
Oxidation States +3
Year Discovered 1880

Identifiers

Element Name Gadolinium
Element Symbol Gd
InChI InChI=1S/Gd
InChIKey UIWYJDYFSGRHKR-UHFFFAOYSA-N

Properties

Atomic Weight

157.249(2)

157.25

157.2

157.25(3)

Electron Configuration

[Xe]6s24f75d1

Atomic Radius

Van der Waals Atomic Radius : 237 pm (Van der Waals)

Empirical Atomic Radius : 180pm (Empirical)

Covalent Atomic Radius : 196(6) pm (Covalent)

Oxidation States

+3

1, 2, 3 ​(a mildly basic oxide)

Ground Level

92

Ionization Energy

6.150 eV

6.14980 ± 0.00004 eV

Electronegativity

Pauling Scale Electronegativity : 1.2(Pauling Scale)

Atomic Spectra

Lines Holdings

Levels Holdings

Physical Description

Solid

Element Classification

Metal

Element Period Number

6

Element Group Number

- Lanthanide

Density

7.90 grams per cubic centimeter

Melting Point

1586 K (1313°C or 2395°F)

1312°C

Boiling Point

3546 K (3273°C or 5923°F)

3000°C

Estimated Crustal Abundance

6.2 milligrams per kilogram

Estimated Oceanic Abundance

7×10-7 milligrams per liter

History

The name derives from the mineral gadolinite, in which it was found, and that had been named for the Finnish rare earth chemist Johan Gadolin. Gadolinium was discovered by the Swiss chemist Jean-Charles Galissard de Marignac in 1886, who produced a white oxide in a samarskite mineral. In 1886, the French chemist Paul-Emile Lecoq de Boisbaudran gave the name gadolinium.

Spectroscopic evidence for the existence of gadolinium was first observed by the Swiss chemist Jean Charles Galissard de Marignac in the minerals didymia and gadolinite ((Ce, La, Nd, Y)2FeBe2Si2O10) in 1880. Today, gadolinium is primarily obtained from the minerals monazite ((Ce, La, Th, Nd, Y)PO4) and bastnasite ((Ce,La,Y)CO3F).

From gadolinite, a mineral named for Gadolin, a Finnish chemist. The rare earth metal is obtained from the mineral gadolinite. Gadolinia, the oxide of gadolinium, was separated by Marignac in 1880 and Lecoq de Boisbaudran independently isolated it from Mosander's yttria in 1886.

Historical Atomic Weights

Year Atomic Weight (uncertainty) [u] Reference
2024 157.249(2)
1969 157.25(3) https://doi.org/10.1351/pac197021010091
1961 157.25 https://doi.org/10.1021/ja00881a001
1955 157.26 https://doi.org/10.1021/ja01595a001
1937 156.9 https://doi.org/10.1039/JR9370001900
1931 157.3 https://doi.org/10.1039/JR9310001617
1925 157.26 https://doi.org/10.1039/CT9252700913
1909 157.3 https://doi.org/10.1021/ja01931a001
1902 156 https://doi.org/10.1007/BF01370337

Historical Isotopic Abundances

Year Isotope Abundance (uncertainty) Reference
2024 152Gd 0.002 04(2)
2024 154Gd 0.021 87(9)
2024 155Gd 0.148 28(60)
2024 156Gd 0.204 93(22)
2024 157Gd 0.156 57(17)
2024 158Gd 0.248 20(20)
2024 160Gd 0.218 11(28)
2013 152Gd 0.0020(3) https://doi.org/10.1515/pac-2015-0503
2013 154Gd 0.0218(2) https://doi.org/10.1515/pac-2015-0503
2013 155Gd 0.1480(9) https://doi.org/10.1515/pac-2015-0503
2013 156Gd 0.2047(3) https://doi.org/10.1515/pac-2015-0503
2013 157Gd 0.1565(4) https://doi.org/10.1515/pac-2015-0503
2013 158Gd 0.2484(8) https://doi.org/10.1515/pac-2015-0503
2013 160Gd 0.2186(3) https://doi.org/10.1515/pac-2015-0503
1997 152Gd 0.0020(1) https://doi.org/10.1351/pac199870010217
1997 154Gd 0.0218(3) https://doi.org/10.1351/pac199870010217
1997 155Gd 0.1480(12) https://doi.org/10.1351/pac199870010217
1997 156Gd 0.2047(9) https://doi.org/10.1351/pac199870010217
1997 157Gd 0.1565(2) https://doi.org/10.1351/pac199870010217
1997 158Gd 0.2484(7) https://doi.org/10.1351/pac199870010217
1997 160Gd 0.2186(19) https://doi.org/10.1351/pac199870010217
1979 152Gd 0.0020(3) https://doi.org/10.1351/pac198052102349
1979 154Gd 0.021(1) https://doi.org/10.1351/pac198052102349
1979 155Gd 0.148(4) https://doi.org/10.1351/pac198052102349
1979 156Gd 0.206(5) https://doi.org/10.1351/pac198052102349
1979 157Gd 0.157(4) https://doi.org/10.1351/pac198052102349
1979 158Gd 0.248(6) https://doi.org/10.1351/pac198052102349
1979 160Gd 0.218(6) https://doi.org/10.1351/pac198052102349
1975 152Gd 0.002 https://doi.org/10.1351/pac197647010075
1975 154Gd 0.022 https://doi.org/10.1351/pac197647010075
1975 155Gd 0.148 https://doi.org/10.1351/pac197647010075
1975 156Gd 0.205 https://doi.org/10.1351/pac197647010075
1975 157Gd 0.157 https://doi.org/10.1351/pac197647010075
1975 158Gd 0.248 https://doi.org/10.1351/pac197647010075
1975 160Gd 0.218 https://doi.org/10.1351/pac197647010075

Description

As with other related rare-earth metals, gadolinium is silvery white, has a metallic luster, and is malleable and ductile. At room temperature, gadolinium crystallizes in the hexagonal, close-packed alpha form. Upon heating to 1235°C, alpha gadolinium transforms into the beta form, which has a body-centered cubic structure.

The metal is relatively stable in dry air, but tarnishes in moist air and forms a loosely adhering oxide film which falls off and exposes more surface to oxidation. The metal reacts slowly with water and is soluble in dilute acid.

Gadolinium has the highest thermal neutron capture cross-section of any known element (49,000 barns).

Users

Gadolinium has the greatest ability to capture thermal neutrons of all known elements and can be used as control rods for nuclear reactors. Unfortunately, the two isotopes best suited for neutron capture, gadolinium-155 and gadolinium-157, are present in gadolinium in small amounts. As a result, gadolinium control rods quickly lose their effectiveness.

Gadolinium can be combined with yttrium to form garnets that have applications in microwave technology. Gadolinium can be alloyed with iron, chromium and other metals to improve their workability and their resistance to high temperatures and oxidation. Gadolinium compounds are used to make phosphors for color televisions.

Gadolinium yttrium garnets are used in microwave applications and gadolinium compounds are used as phosphors in color television sets.

The metal has unusual superconductive properties. As little as 1 percent gadolinium improves the workability and resistance of iron, chromium, and related alloys to high temperatures and oxidation.

Gadolinium ethyl sulfate has extremely low noise characteristics and may find use in duplicating the performance of amplifiers, such as the maser.

The metal is ferromagnetic. Gadolinium is unique for its high magnetic movement and for its special Curie temperature (above which ferromagnetism vanishes) lying just at room temperature, meaning it could be used as a magnetic component that can sense hot and cold.

Sources

Gadolinium is found in several other minerals, including monazite and bastnasite, both of which are commercially important. With the development of ion-exchange and solvent extraction techniques, the availability and prices of gadolinium and the other rare-earth metals have greatly improved. The metal can be prepared by the reduction of the anhydrous fluoride with metallic calcium.

Compounds

See more information at the Gadolinium compound page.

Element Forms

CID Name Formula SMILES Molecular Weight
23982 gadolinium Gd [Gd] 157.25
168050 gadolinium(3+) Gd+3 [Gd+3] 157.25
161049 gadolinium-153 Gd [153Gd] 152.92176
166988 gadolinium-159 Gd [159Gd] 158.92640
177487 gadolinium-160 Gd [160Gd] 159.92706
177560 gadolinium-158 Gd [158Gd] 157.92411
189930 gadolinium-161 Gd [161Gd] 160.92968
9898866 gadolinium-148 Gd [148Gd] 147.91812
177519 gadolinium-149 Gd [149Gd] 148.91935
177520 gadolinium-151 Gd [151Gd] 150.92035
177522 gadolinium-147 Gd [147Gd] 146.91910
177523 gadolinium-146 Gd [146Gd] 145.91832
10219555 gadolinium-155 Gd [155Gd] 154.92263
11171109 gadolinium-156 Gd [156Gd] 155.92213
11966234 gadolinium(2+) Gd+2 [Gd+2] 157.25
185533 gadolinium-145 Gd [145Gd] 144.9217
44154792 gadolinium-152 Gd [152Gd] 151.91980
10130059 gadolinium-153(3+) Gd+3 [153Gd+3] 152.92176
10219563 gadolinium-157 Gd [157Gd] 156.92397
11400878 gadolinium-154 Gd [154Gd] 153.92087
51352783 gadolinium-159(3+) Gd+3 [159Gd+3] 158.92640

Isotopes

Stable Isotope Count 5
Summary Natural gadolinium is a mixture of seven isotopes, but 17 isotopes of gadolinium are now recognized. Although two of these, 155Gd and 157Gd, have excellent capture characteristics, they are only present naturally in low concentrations. As a result, gadolinium has a very fast burnout rate and has limited use as a nuclear control rod material.

Isotopes in Earth/Planetary Science

The lunar surface is continuously exposed to cosmic radiation, and the interaction between planetary material and cosmic rays produces secondary neutrons. The neutron flux can be investigated using the large neutron capture cross sections of 149Sm, 155Gd, and 157Gd. For example, 157Gd will absorb neutrons and be converted to 158Gd. On a cross plot of n(158Gd)/n(160Gd) isotope-amount ratio and n(157Gd)/n(160Gd) isotope-amount ratio (Fig. IUPAC.64.1), values will move from the lower right corner to the upper left corner of the cross plot with increasing time or increasing flux.

Fig. IUPAC.64.1: Cross plot of n(¹⁵⁸Gd)/n(¹⁶⁰Gd) and n(¹⁵⁷Gd)/n(¹⁶⁰Gd) isotope-amount ratios of samples from Apollo lunar sites A-12 and A-15 (modified from [452]).

[452] H. Hidaka, M. Ebihara, S. Yoneda. “Samarium and gadolinium isotopic compositions of lunar samples”, in 30th Annual Lunar and Planetary Science Conference.

Isotopes in Medicine

The addition of 157Gd to Neutron Capture Therapy (NCT) has been shown to be more effective at targeting tumors than the previous method of using only 10B for the treatment (Fig. IUPAC.64.2) [453]. 153Gd (with a half-life of 0.66 years) is used in the production of photon line sources (an optical source that emits one or more spectrally narrow lines as opposed to a continuous spectrum) to manufacture 153Gd line sources [454]. 153Gd is also used as a photon source of the dual-photon absorptiometry (DPA) technique that is used to measure bone mineral content (BMC). Studies for this technique have been conducted in horses and humans [455], [456].

Fig. IUPAC.64.2: Patient undergoing neutron therapy. The red lasers cross to target the patient’s tumor. A beam of neutrons is fired at the target to stop the growth and eradicate the tumor. (Photo Source: Reidar Hahn, Fermilab Visual Media Services Photo Database, Fermi National Accelerator Laboratory) [457].

[453] C. N. Culbertson, T. Jevremovic. Phys. Med. Biol.48, 3943 (2003).
[454] V. M. Lebedev, J. N. Gordeev, E. A. Karelin, V. D. Gavrilov. Appl. Radiat. Isot.53, 829 (2000).
[455] A. Moure, P. Reichmann, H. R. Gamba. Phys. Med. Biol.48, 3851 (2003).
[456] P. Tothill, M. A. Smith, D. Sutton. Br. J. Radiol.56, 829 (1983).
[457] R. Hahn. “Neutron therapy – Christine Andorf with patient in treatment room, Fermilab neg. no: 05-0086-04D”, in Fermilab Visual Media Services Photo Database.

Isotope Mass and Abundance

Isotope Atomic Mass (uncertainty) [u] Abundance (uncertainty)
152Gd 151.919 799(8) 0.002 04(2) 0.0020(1)
154Gd 153.920 873(8) 0.021 87(9) 0.0218(3)
155Gd 154.922 630(8) 0.148 28(60) 0.1480(12)
156Gd 155.922 131(8) 0.204 93(22) 0.2047(9)
157Gd 156.923 968(8) 0.156 57(17) 0.1565(2)
158Gd 157.924 112(8) 0.248 20(20) 0.2484(7)
160Gd 159.927 062(9) 0.218 11(28) 0.2186(19)

Atomic Mass, Half Life, and Decay

Nuclide Atomic Mass and Uncertainty [u] Half Life and Uncertainty Discovery Year Decay Modes, Intensities and Uncertainties [%]
133Gd 132.961288 ± 0.000537 [Estimated] 10 ms [Estimated] β+ ?; β+p ?
134Gd 133.955416 ± 0.000429 [Estimated] 400 ms [Estimated] β+ ?; β+p ?
135Gd 134.952496 ± 0.000429 [Estimated] 1.1 s ± 0.2 1996 β+=100%; β+p≈2%
136Gd 135.947300 ± 0.00032 [Estimated] 1 s >200ns [Estimated] 2000 β+ ?; β+p ?
137Gd 136.945020 ± 0.00032 [Estimated] 2.2 s ± 0.2 1999 β+=100%; β+p=?
138Gd 137.940247 ± 0.000215 [Estimated] 4.7 s ± 0.9 1985 β+=100%
138Gdm 137.940247 ± 0.000215 [Estimated] 6.2 us ± 0.2 1997 IT=100%
139Gd 138.938130 ± 0.00021 [Estimated] 5.7 s ± 0.3 1983 β+=100%; β+p=?
139Gdm 138.938130 ± 0.00021 [Estimated] 4.8 s ± 0.9 1983 β+=100%; β+p=?
140Gd 139.933674000 ± 0.00003 15.8 s ± 0.4 1985 β+=100%; e+=67±0.8%; ε=33±0.8%
141Gd 140.932126000 ± 0.000021213 14 s ± 4 1986 β+=100%; β+p=0.03±0.1%
141Gdm 140.932126000 ± 0.000021213 24.5 s ± 0.5 1986 β+=89±0.2%; IT=11±0.2%
142Gd 141.928116000 ± 0.00003 70.2 s ± 0.6 1986 β+=100%; ε=52±0.5%; e+=48±0.5%
143Gd 142.926750678 ± 0.000215032 39 s ± 2 1975 β+=100%; β+p=?; β+α=?
143Gdm 142.926750678 ± 0.000215032 110.0 s ± 1.4 1973 β+=100%; β+p=?; β+α=?
144Gd 143.922963000 ± 0.00003 4.47 m ± 0.06 1968 β+=100%
144Gdm 143.922963000 ± 0.00003 145 ns ± 30 1978 IT=100%
145Gd 144.921710051 ± 0.000021165 23.0 m ± 0.4 1959 β+=100%
145Gdm 144.921710051 ± 0.000021165 85 s ± 3 1969 IT=94.3±0.5%; β+=5.7±0.5%
146Gd 145.918318513 ± 0.000004376 48.27 d ± 0.09 1957 ε=100%
147Gd 146.919101014 ± 0.000002025 38.06 h ± 0.12 1957 β+=100%
147Gdm 146.919101014 ± 0.000002025 510 ns ± 20 1982 IT=100%
148Gd 147.918121414 ± 0.000001566 71.3 y ± 1.0 1953 α=100%; 2β+ ?
149Gd 148.919347666 ± 0.000003553 9.28 d ± 0.10 1951 β+=100%; α=4.3e-4±1%
150Gd 149.918663949 ± 0.0000065 1.79 My ± 0.08 1953 α=100%; 2β+ ?
151Gd 150.920354922 ± 0.000003212 123.9 d ± 1.0 1950 ε=100%; α≈1.1e-6±0.6%
152Gd 151.919798414 ± 0.000001081 108 Ty ± 8 1938 IS=0.20±0.3%; α=100%; 2β+ ?
153Gd 152.921756945 ± 0.000001075 240.6 d ± 0.7 1947 ε=100%
153Gdm 152.921756945 ± 0.000001075 3.5 us ± 0.4 1979 IT=100%
153Gdn 152.921756945 ± 0.000001075 76.0 us ± 1.4 1967 IT=100%
154Gd 153.920872974 ± 0.000001066 Stable 1938 IS=2.18±0.2%
155Gd 154.922629356 ± 0.000001055 Stable 1933 IS=14.80±0.9%
155Gdm 154.922629356 ± 0.000001055 31.97 ms ± 0.27 1967 IT=100%
156Gd 155.922130120 ± 0.000001054 Stable 1933 IS=20.47±0.3%
156Gdm 155.922130120 ± 0.000001054 1.3 us ± 0.1 1969 IT=100%
157Gd 156.923967424 ± 0.000001048 Stable 1933 IS=15.65±0.4%
157Gdm 156.923967424 ± 0.000001048 460 ns ± 40 1964 IT=100%
157Gdn 156.923967424 ± 0.000001048 18.5 us ± 2.3 1961 IT=100%
158Gd 157.924111200 ± 0.000001048 Stable 1933 IS=24.84±0.8%
159Gd 158.926395822 ± 0.000001051 18.479 h ± 0.004 1949 β-=100%
160Gd 159.927061202 ± 0.000001206 Stable >31Ey 1933 IS=21.86±0.3%; 2β- ?
161Gd 160.929676267 ± 0.000001614 3.646 m ± 0.003 1949 β-=100%
162Gd 161.930991812 ± 0.000004254 8.4 m ± 0.2 1967 β-=100%
163Gd 162.934096640 ± 0.000000855 68 s ± 3 1982 β-=100%
163Gdm 162.934096640 ± 0.000000855 23.5 s ± 1.0 2014 IT= ?; β- ?
164Gd 163.935916193 ± 0.000001073 45 s ± 3 1988 β-=100%
164Gdm 163.935916193 ± 0.000001073 589 ns ± 18 2017 IT=100%
165Gd 164.939317080 ± 0.0000014 11.6 s ± 1.0 1998 β-=100%
166Gd 165.941630413 ± 0.0000017 5.1 s ± 0.8 2005 β-=100%
166Gdm 165.941630413 ± 0.0000017 950 ns ± 60 2014 IT=100%
167Gd 166.945490012 ± 0.000005596 4.2 s ± 0.3 2012 β-=100%
168Gd 167.948309 ± 0.000322 [Estimated] 3.03 s ± 0.16 1985 β-=100%
169Gd 168.952882 ± 0.000429 [Estimated] 750 ms ± 210 2012 β-=100%; β-n ?
170Gd 169.956146 ± 0.000537 [Estimated] 420 ms ± 130 2012 β-=100%; β-n ?
171Gd 170.961127 ± 0.000537 [Estimated] 300 ms >550ns [Estimated] 2018 β- ?; β-n ?
172Gd 171.964605 ± 0.000322 [Estimated] 160 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
    Gadolinium

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