Sm 62

Samarium (Sm)

lanthanide

Period: 6 Block: s

Solid

Standard Atomic Weight

Electron configuration

[Xe] 6s² 4f⁶

Melting point

1073.85 °C (1347 K)

Boiling point

1793.85 °C (2067 K)

Density

7520 kg/m³

Oxidation states

0, +1, +2, +3

Electronegativity (Pauling)

1.17

Ionization energy (1st)

Discovery year

1878

Atomic radius

185 pm

Details

Name origin Named after the mineral samarskite.

Discovery country France

Discoverers Paul Émile Lecoq de Boisbaudran

Samarium is a lanthanide metal with atomic number 62. It is a typical rare-earth element in its trivalent chemistry, but it is also notable for accessible divalent compounds and for the strong neutron-absorbing isotope ¹⁴⁹Sm. The element occurs with other light rare earths in minerals such as monazite and bastnäsite. Its technological importance is concentrated in permanent magnets, neutron control, phosphors, and specialized chemical reducing agents.

Samarium has a bright silver luster and is reasonably stable in air. Three crystal modifications of the metal exist, with transformations at 734 and 922°C. The metal ignites in air at about 150°C. The sulfide has excellent high-temperature stability and good thermoelectric efficiencies up to 1100°C.

The name derives from the mineral samarskite, in which it was found and that had been named for Colonel Samarski, a Russian mine official. Samarium was originally discovered in 1878 by the Swiss chemist Marc Delafontaine, who called it decipium. It was also discovered by the French chemist Paul-Emile Lecoq de Boisbaudran in 1879. In 1881, Delafontaine determined that his decipium could be resolved into two elements, one of which was identical to Boisbaudran's samarium. In 1901, the French chemist Eugène-Anatole Demarçay showed that this samarium earth also contained europium.

Samarium was observed spectroscopically by Jean Charles Galissard de Marignac, a Swiss chemist, in a material known as dydimia in 1853. Paul-Émile Lecoq de Boisbaudran, a French chemist, was the first to isolate samarium from the mineral samarskite ((Y, Ce, U, Fe)3(Nb, Ta, Ti)5O16) in 1879. Today, samarium is primarily obtained through an ion exchange process from monazite sand ((Ce, La, Th, Nd, Y)PO4), a material rich in rare earth elements that can contain as much as 2.8% samarium.

Discovered spectroscopically by its sharp absorption lines in 1879 by Lecoq de Boisbaudran in the mineral samarskite, named in honor of a Russian mine official, Col. Samarski.

Read about Samarium on Wikipedia

Images

Properties

Physical

Atomic radius (empirical) 185 pm

Covalent radius 198 pm

Van der Waals radius 229 pm

Density

Molar volume 0.0199 L/mol

Phase at STP solid

Melting point 1073.85 °C

Boiling point 1793.85 °C

Specific heat capacity 0.197 J/(g·K)

Molar heat capacity 29.54 J/(mol·K)

Crystal structure rhombohedral

Chemical

Electronegativity (Pauling) 1.17

Electron affinity

Ionization energy (1st)

Ionization energy (2nd)

Ionization energy (3rd)

Ionization energy (4th)

Ionization energy (5th)

Oxidation states 0, +1, +2, +3

Valence electrons 3

Electron configuration

Electron configuration (semantic)

Thermodynamic

Heat of fusion 0.08934031 eV

Heat of vaporization 1.71011 eV

Heat of sublimation 2.145411 eV

Heat of atomization 2.145411 eV

Atomization enthalpy

Nuclear

Stable isotopes 5

Discovery year 1878

Abundance

Abundance (Earth's crust) 7.05 mg/kg

Abundance (ocean)

Reactivity

N/A

Crystal Structure

Lattice constant a 900 pm

Electronic Structure

Electrons per shell 2, 8, 18, 24, 8, 2

Identifiers

CAS number 7440-19-9

Term symbol

InChI InChI=1S/Sm

InChI Key KZUNJOHGWZRPMI-UHFFFAOYSA-N

Electron Configuration Measured

Ion charge

Protons 62

Electrons 62

Charge Neutral

Configuration Sm: 4f⁶ 6s²

[Xe] 4f⁶ 6s²

1s² 2s² 2p⁶ 3s² 3p⁶ 3d¹⁰ 4s² 4p⁶ 4d¹⁰ 5s² 5p⁶ 4f⁶ 6s²

Orbital diagram

↑↓

2/2

↑↓

2/2

↑↓

6/6

↑↓

2/2

↑↓

6/6

↑↓

2/2

↑↓

10/10

↑↓

6/6

↑↓

2/2

↑↓

10/10

↑↓

6/6

↑↓

2/2

↑

6/14 6↑

Total electrons: 62 Unpaired: 6

Atomic model

Protons 62

Neutrons 90

Electrons 62

Mass number 152

Stability Stable

Isotopes change neutron count, mass, and stability — not the electron configuration of a neutral atom.

Schematic atomic model, not to scale.

Atomic Fingerprint

Emission / Absorption Spectrum

Emission Visible: 380–750 nm

Isotope Distribution

Mass number	Atomic mass (u)	Natural abundance	Half-life
144 Stable	143.9120065 ± 0.0000021	3.0700%	Stable
150 Stable	149.9172829 ± 0.0000018	7.3800%	Stable
152 Stable	151.9197397 ± 0.0000018	26.7500%	Stable

Measured

Phase / State

Solid 25 °C (298.15 K)

Reason: 1048.8 °C below melting point (1073.85 °C)

Melting point 1073.85 °C

Boiling point 1793.85 °C

Below melting by 1048.8 °C

0 K Current temperature: 25 °C 6000 K

Phase timeline

Schematic, not to scale

Solid

Liquid

Gas

Melting

Boiling

25°C

Solid

Liquid

Gas

Current

Phase transition points

Melting point Literature

1073.85 °C

Boiling point Literature

1793.85 °C

Current phase Calculated
Solid

Transition energies

Heat of fusion Literature

0.08934031 eV

Energy required to melt 1 mol at melting point

Heat of vaporization Literature

1.71011 eV

Energy required to vaporize 1 mol at boiling point

Heat of sublimation Literature

2.145411 eV

Energy required to sublime 1 mol at sublimation point

Density

Reference density Literature

7520 kg/m³

At standard conditions

Current density Calculated

7520 kg/m³

At standard conditions

Atomic Spectra

Showing 10 of 62 Atomic Spectra. Sorted by ion charge (ascending).

Lines Holdings ?

Ion	Charge	Total lines	Transition probabilities	Level designations
Sm I	0	162	7	11
Sm II	+1	635	7	14

NIST Lines Holdings →

Levels Holdings ?

Ion	Charge	Levels
Sm I	0	501
Sm II	+1	377
Sm III	+2	58
Sm IV	+3	24
Sm V	+4	2
Sm VI	+5	2
Sm VII	+6	2
Sm VIII	+7	2
Sm IX	+8	2
Sm X	+9	2

NIST Levels Holdings →

62 Sm 150.36

Samarium — Atomic Orbital Visualizer

[Xe]6s24f6

Energy levels 2 8 18 24 8 2

Oxidation states 0, +1, +2, +3

HOMO 4f n=4 · l=3 · m=-3

Samarium — Atomic Orbital Visualizer Preview

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62 Sm 150.36

Samarium — Crystal Structure Visualizer

Crystal structure data not available

Crystal structure: rhombohedral

Ionic Radii

Charge	Coordination	Spin	Radius
+2	7	N/A	122 pm
+2	8	N/A	127 pm
+2	9	N/A	132 pm
+3	6	N/A	95.8 pm
+3	7	N/A	102 pm
+3	8	N/A	107.89999999999999 pm
+3	9	N/A	113.19999999999999 pm
+3	12	N/A	124 pm

Compounds

150.400 u

152.922 u

Sm+3

150.400 u

153.922 u

144.913 u

151.920 u

146.915 u

145.913 u

150.920 u

149.917 u

155.926 u

148.917 u

143.912 u

154.925 u

140.918 u

141.915 u

Sm+3

151.920 u

Sm+3

152.922 u

147.915 u

156.928 u

Isotopes (3)

Twenty one isotopes of samarium exist. Natural samarium is a mixture of several isotopes, three of which are unstable with long half-lives.

Mass number	Atomic mass (u)	Natural abundance	Half-life	Decay mode
144 Stable	143.9120065 ± 0.0000021	3.0700% ± 0.0700%	Stable	stable
150 Stable	149.9172829 ± 0.0000018	7.3800% ± 0.0100%	Stable	stable
152 Stable	151.9197397 ± 0.0000018	26.7500% ± 0.1600%	Stable	stable

144 Stable

Atomic mass (u) 143.9120065 ± 0.0000021

Natural abundance 3.0700% ± 0.0700%

Half-life Stable

Decay mode

stable

150 Stable

Atomic mass (u) 149.9172829 ± 0.0000018

Natural abundance 7.3800% ± 0.0100%

Half-life Stable

Decay mode

stable

152 Stable

Atomic mass (u) 151.9197397 ± 0.0000018

Natural abundance 26.7500% ± 0.1600%

Half-life Stable

Decay mode

stable

Extended Properties

Covalent Radii (Extended)

Covalent radius (Pyykkö)

Covalent radius (Pyykkö, double)

Van der Waals Radii

Alvarez

UFF

MM3

Atomic & Metallic Radii

Atomic radius (Rahm)

Numbering Scales

Mendeleev

Pettifor

Glawe

Electronegativity Scales

Ghosh

Miedema

Gunnarsson–Lundqvist

Robles–Bartolotti

Polarizability & Dispersion

Dipole polarizability

Dipole polarizability (unc.)

C₆ (Gould–Bučko)

Miedema Parameters

Miedema molar volume

Miedema electron density

Supply Risk & Economics

Production concentration

Relative supply risk

Reserve distribution

Political stability (top producer)

Political stability (top reserve)

Phase Transitions & Allotropes

Melting point	1345.15 K
Boiling point	2067.15 K

Oxidation State Categories

+2 extended

+1 extended

0 extended

+3 main

Advanced Reference Data

Screening Constants (13)

n	Orbital	σ
1	s	1.2217
2	p	4.269
2	s	16.2652
3	d	13.7711
3	p	19.5815
3	s	19.9736
4	d	33.7604
4	f	38.4684
4	p	30.912
4	s	29.7076

Crystal Radii Detail (8)

Charge	CN	r_crystal (pm)	Origin
2	VII	136
2	VIII	141
2	IX	146
3	VI	109.8	from r^3 vs V plots,
3	VII	116	estimated,
3	VIII	121.9	from r^3 vs V plots,
3	IX	127.2	from r^3 vs V plots,
3	XII	138	calculated,

Isotope Decay Modes (52)

Isotope	Mode	Intensity
128	B+	—
128	B+p	—
129	B+	100%
129	B+p	—
130	B+	—
131	B+	100%
131	B+p	—
132	B+	100%
132	B+p	—
133	B+	100%

X‑ray Scattering Factors (508)

Energy (eV)	f₁	f₂
10	—	0.18764
10.1617	—	0.19534
10.3261	—	0.20334
10.4931	—	0.21168
10.6628	—	0.22036
10.8353	—	0.22939
11.0106	—	0.2388
11.1886	—	0.24859
11.3696	—	0.25878
11.5535	—	0.26939

Additional Data

Estimated Crustal Abundance

The estimated element abundance in the earth's crust.

7.05 milligrams per kilogram

References (1)

[5] Samarium https://education.jlab.org/itselemental/ele062.html

Estimated Oceanic Abundance

The estimated element abundance in the earth's oceans.

4.5×10-7 milligrams per liter

References (1)

[5] Samarium https://education.jlab.org/itselemental/ele062.html

Sources

Sources of this element.

Samarium is found along with other members of the rare-earth elements in many minerals, including monazite and bastnasite, which are commercial sources. It occurs in monazite to the extent of 2.8%. While misch metal containing about 1% of samarium metal, has long been used, samarium has not been isolated in relatively pure form until recently. Ion-exchange and solvent extraction techniques have recently simplified separation of the rare earths from one another; more recently, electrochemical deposition, using an electrolytic solution of lithium citrate and a mercury electrode, is said to be a simple, fast, and highly specific way to separate the rare earths. Samarium metal can be produced by reducing the oxide with lanthanum.

References (1)

[6] Samarium https://periodic.lanl.gov/62.shtml

References

(9)

1 PubChem

Data deposited in or computed by PubChem

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2 Atomic Mass Data Center (AMDC), International Atomic Energy Agency (IAEA)

The half-life and atomic mass data was provided by the Atomic Mass Data Center at the International Atomic Energy Agency.

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3 IUPAC Commission on Isotopic Abundances and Atomic Weights (CIAAW)

Samarium

Element data are cited from the Atomic weights of the elements (an IUPAC Technical Report). The IUPAC periodic table of elements can be found at https://iupac.org/what-we-do/periodic-table-of-elements/. Additional information can be found within IUPAC publication doi:10.1515/pac-2015-0703 Copyright © 2020 International Union of Pure and Applied Chemistry.

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4 IUPAC Periodic Table of the Elements and Isotopes (IPTEI)

The information are cited from Pure Appl. Chem. 2018; 90(12): 1833-2092, https://doi.org/10.1515/pac-2015-0703.

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License note: 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.

5 Jefferson Lab, U.S. Department of Energy

Samarium

Thomas Jefferson National Accelerator Facility (Jefferson Lab) is one of 17 national laboratories funded by the U.S. Department of Energy. The lab's primary mission is to conduct basic research of the atom's nucleus using the lab's unique particle accelerator, known as the Continuous Electron Beam Accelerator Facility (CEBAF). For more information visit https://www.jlab.org/

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License note: Please see citation and linking information: https://education.jlab.org/faq/index.html

6 Los Alamos National Laboratory, U.S. Department of Energy

Samarium

The periodic table at the LANL (Los Alamos National Laboratory) contains basic element information together with the history, source, properties, use, handling and more. The provenance data may be found from the link under the source name.

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7 NIST Physical Measurement Laboratory

Samarium

The periodic table contains NIST's critically-evaluated data on atomic properties of the elements. The provenance data that include data for atomic spectroscopy, X-ray and gamma ray, radiation dosimetry, nuclear physics, and condensed matter physics may be found from the link under the source name. Ref: https://www.nist.gov/pml/atomic-spectra-database

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8 PubChem Elements

Samarium

This section provides all form of data related to element Samarium.

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9 PubChem Elements

Samarium

The element property data was retrieved from publications.

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Last updated: May 1, 2026

Data verified: May 12, 2026

Content is reviewed against latest scientific data.