Ruthenium vs Samarium

Ruthenium

Samarium

Samarium vs Ruthenium

Periodic Table

Symbol

Group Number

Not Available

Period Number

Block

d block

f block

Element Family

Transition Metal

Lanthanide

CAS Number

7440188

99+

7440199

99+

Space Group Name

P63/mmc

R_ 3m

Space Group Number

194.00

166.00

Facts

Interesting Facts

Ruthenium element has been extracted from used nuclear fuel.
Ruthenium metal also produces as a by-product of the Nickel mining.

Samarium metals helps stimulating body metabolism.
Samarium metals was 1st observed by Jean Charles Galissard de Marignac in Dydimia in 1853.

Sources

By-product of Nickel Refining, Found in Minerals, Mining

Found in Minerals, Mining, Ores of Minerals

History

Who Discovered

Karl Ernst Claus

Lecoq de Boisbaudran

Discovery

In 1844

In 1879

Abundance

Abundance In Universe

4 * 10^-7 %

5 * 10^-7 %

Abundance In Sun

~0.0000005 %

~0.0000001 %

Abundance In Meteorites

0.00 %

Abundance In Earth's Crust

0.00 %

99+

0.00 %

Abundance In Oceans

0.00 %

Uses

Uses & Benefits

It is used for producing chip resistors and contact.

Ruthenium oxide is used to coat the anodes cells for chlorine production in chemical industry. It also works as catalysts for ammonia and acetic acid reaction.

Magnets of Samarium cobalt alloy are stronger than that of Iron and hence, they are used in microwave application.

Samarium metal also used in optical lasers and infrared absorbing glasses and as a neutron absorber.

Industrial Uses

Aerospace Industry, Automobile Industry, Chemical Industry, Electrical Industry, Electronic Industry

Medical Uses

Medical Research

Other Uses

Alloys

Alloys, In Nuclear Reactors

Biological Properties

Toxicity

Low Toxic

Slightly Toxic

Present in Human Body

Yes

In Blood

Not Available

0.01 Blood/mg dm-3

Physical Properties

Melting Point

2,250.00 °C

1,072.00 °C

99+

Boiling Point

3,900.00 °C

1,900.00 °C

99+

Appearance

Physical State

Solid

Color

Silvery White

Luster

Metallic

Lustrous

Hardness

Mohs Hardness

6.50

Not Available

Brinell Hardness

2,160.00 MPa

441.00 MPa

Vickers Hardness

Not Available

412.00 MPa

Speed of Sound

5,970.00 m/s

2,130.00 m/s

99+

Optical Properties

Allotropes

α Allotropes

Not Available

β Allotropes

Not Available

γ Allotropes

Not Available

Chemical Properties

Chemical Formula

Isotopes

Known Isotopes

Electronegativity

Pauling Electronegativity

2.20

1.17

Allred Rochow Electronegativity

1.42

1.07

Allen Electronegativity

1.54

Not Available

Electropositivity

Pauling Electropositivity

1.80

99+

2.83

Ionization Energies

1st Energy Level

710.20 kJ/mol

544.50 kJ/mol

99+

2nd Energy Level

710.22 kJ/mol

99+

1,070.00 kJ/mol

99+

3rd Energy Level

2,747.00 kJ/mol

2,260.00 kJ/mol

99+

4th Energy Level

Not Available

3,990.00 kJ/mol

Electrochemical Equivalent

1.26 g/amp-hr

99+

1.87 g/amp-hr

Electron Work Function

4.71 eV

2.70 eV

99+

Other Chemical Properties

Anti Corrosion, Ionization, Radioactive Isotopes, Solubility

Ionization, Radioactive Isotopes

Atomic Properties

Atomic Number

99+

Electron Configuration

[Kr] 4d⁷ 5s¹

[Xe] 4f⁶ 6s²

Crystal Structure

Hexagonal Close Packed (HCP)

Rhombohedral (RHO)

Crystal Lattice

rystal-Structure-of-Ruthenium.jpg#100

RHO-Crystal-Structure-of-Samarium.jpg#100

Atom

Number of Protons

99+

Number of Neutrons

99+

Number of Electrons

99+

Radius of an Atom

Atomic Radius

134.00 pm

99+

180.00 pm

Covalent Radius

146.00 pm

198.00 pm

Van der Waals Radius

200.00 pm

229.00 pm

Atomic Weight

101.07 amu

99+

150.36 amu

99+

Atomic Volume

8.30 cm3/mol

99+

19.95 cm3/mol

Adjacent Atomic Numbers

Previous Element

Next Element

Valence Electron Potential

64.00 (-eV)

44.80 (-eV)

Lattice Constant

270.59 pm

99+

362.10 pm

Lattice Angles

π/2, π/2, 2 π/3

Lattice C/A Ratio

1.58

Not Available

Mechanical Properties

Density

Density At Room Temperature

12.45 g/cm³

7.52 g/cm³

99+

Density When Liquid (at m.p.)

10.65 g/cm3

7.16 g/cm3

Tensile Strength

Not Available

Viscosity

Not Available

Vapor Pressure

Vapor Pressure at 1000 K

Not Available

0.94 (Pa)

Vapor Pressure at 2000 K

0.00 (Pa)

Not Available

Elasticity properties

Shear Modulus

173.00 GPa

19.50 GPa

Bulk Modulus

220.00 GPa

37.80 GPa

Young's Modulus

447.00 GPa

49.70 GPa

Poisson Ratio

0.30

0.27

Other Mechanical Properties

Ductile, Malleable

Magnetic Properties

Magnetic Characteristics

Specific Gravity

12.45

7.52

99+

Magnetic Ordering

Paramagnetic

Electrical Properties

Electrical Property

Conductor

Resistivity

71.00 nΩ·m

0.94 nΩ·m

99+

Electrical Conductivity

0.14 10⁶/cm Ω

0.01 10⁶/cm Ω

99+

Electron Affinity

101.30 kJ/mol

50.00 kJ/mol

Thermal Properties

Specific Heat

0.24 J/(kg K)

0.20 J/(kg K)

Molar Heat Capacity

24.06 J/mol·K

99+

29.54 J/mol·K

Thermal Conductivity

117.00 W/m·K

13.30 W/m·K

99+

Critical Temperature

Not Available

Thermal Expansion

6.40 µm/(m·K)

99+

12.70 µm/(m·K)

Enthalpy

Enthalpy of Vaporization

567.80 kJ/mol

166.40 kJ/mol

99+

Enthalpy of Fusion

25.50 kJ/mol

8.62 kJ/mol

Enthalpy of Atomization

603.00 kJ/mol

209.00 kJ/mol

99+

Standard Molar Entropy

28.50 J/mol.K

99+

69.60 J/mol.K

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