Atomic Number 75

Rhenium (Re)

Transition

Group7

Period6

BlockD

State @ 25°CSolid

Valence Electrons2 (d-block, variable in compounds)

Electron Config (Noble)[Xe] 6s2 4f14 5d5

75ReRhenium186.21

Tap related elements to compare trends across group and period.

Navigate neighbors← W Os →

Physical Properties

How this element behaves in real-world conditions.

State (25°C): Solid
Density: 21.02 g/cm³
Melting Point: 3186 °C
Boiling Point: 5596 °C

Atomic Structure

Core identity and periodic table positioning.

Atomic Number: 75
Atomic Weight: 186.21
Atomic Radius: 217 pm
Block: D
Group: 7
Period: 6

Electromagnetic Properties

How this element attracts and exchanges electrons.

Electronegativity: 1.9
Ionization Energy: 7.88 eV
Electron Affinity: 0.15 eV
Metallic Character: Metal

Hero / Identity Section

Core identity profile for Rhenium with periodic placement and electron context.

Element Name: Rhenium
Symbol: Re
Atomic Number: 75
Atomic Mass: 186.21
Group: 7
Period: 6
Block: D
Category: Transition
Standard State: Solid
Electron Configuration (Full): 1s2 2s2 2p6 3s2 3p6 4s2 3d10 4p6 5s2 4d10 5p6 6s2 4f14 5d5
Electron Configuration (Noble Gas): [Xe] 6s2 4f14 5d5
Valence Electrons: 2 (d-block, variable in compounds)

Quick Facts Card (Table Layout)

Fast-reference values for physical and energetic properties.

Atomic Radius

217 pm

Ionic Radius

Not available in current dataset

Electronegativity (Pauling)

1.9

1st Ionization Energy

7.88 eV

Electron Affinity

0.15 eV

Density

21.02 g/cm³

Melting Point

3,186 °C

Boiling Point

5,596 °C

Heat Capacity

Not available in current dataset

Thermal Conductivity

Not available in current dataset

Visual Components

Visual learning views for table position, shells, orbitals, and phase behavior.

Highlighted Position in Periodic Table Grid

Row 6, Column 7

Bohr Model Diagram

Educational shell model for electron arrangement.

Electron Shell Diagram

K shell2
L shell8
M shell18
N shell32
O shell13
P shell2

Orbital Configuration Diagram

1s2/2

2s2/2

2p6/6

3s2/2

3p6/6

4s2/2

3d10/10

4p6/6

5s2/2

4d10/10

5p6/6

6s2/2

4f14/14

5d5/10

Phase Illustration

Solid

Solid lattice

Atomic Structure Section

Nuclear composition and electron shielding interpretation.

Protons: 75
Neutrons (Most Abundant Isotope Estimate): 111
Electrons: 75
Electron Configuration Breakdown: 2 • 8 • 18 • 32 • 13 • 2
Shielding Explanation: Core electrons (~73) shield part of the nucleus, reducing attraction felt by outer electrons compared with the full nuclear charge.
Effective Nuclear Charge (Estimate): 2

Chemical Properties Section

Category-guided chemistry behavior with periodic context for comparison.

Common Oxidation States: Variable (often +2, +3, and higher/lower states depending on element)
Reactivity Summary: Moderate to broad reactivity range with strong dependence on oxidation state and ligands.
Acid/Base Behavior: Many oxides/hydroxides are amphoteric or weakly basic; behavior varies by element/state.
Bonding Behavior: Displays metallic, ionic, and coordination (complex) bonding patterns.
Typical Compounds: Oxides, Halides, Coordination complexes
Periodic Trend Comparison (Group Neighbors): Compared with Tc, this element is lower in the group and typically has a larger atomic size and lower ionization tendency. Compared with Bh, this element is higher in the group and often shows a smaller radius with stronger effective attraction to valence electrons.

Isotopes & Nuclear Data

Isotope stability and abundance notes for learning-oriented nuclear context.

Stable Isotopes: Stable isotopes are known. Most abundant isotope is commonly represented near Re-186.
Radioactive Isotopes: Radioactive isotopes exist alongside stable isotopes.
Natural Abundance (%): Naturally occurring with isotope-dependent abundance.
Half-life (If Applicable): Stable isotopes have no half-life; radioactive isotopes have isotope-specific half-lives.
Nuclear Spin (Optional Advanced): Advanced isotope-level data is not included in the current core dataset.
Most Abundant Isotope (Estimate): Re-186

Applications & Uses

How this element appears in industry, biology, medicine, and technology.

Industrial Uses: Core materials for catalysts, alloys, structural metals, and chemical manufacturing.
Biological Role: Several transition metals are essential trace nutrients; excess can be toxic.
Medical Use: Used in diagnostics, implants, imaging agents, and therapeutic complexes.
Technological Relevance: Critical for electronics, catalysis, batteries, magnets, and manufacturing.
Environmental Impact: Can persist and bioaccumulate depending on element and oxidation state.

Safety & Handling

General hazard guidance for educational reference and lab awareness.

Toxicity: Toxicity spans low to high and is oxidation-state dependent; monitor exposure carefully.
Flammability: Bulk metals are generally low flammability; powders may be combustible.
Storage Considerations: Store according to specific oxidation state/compound hazards; avoid incompatible reagents.
Regulatory Classification: Often regulated by occupational exposure limits and compound-specific hazard classes.

Atomic Number 75

Rhenium (Re)

Transition

Group7

Period6

BlockD

State @ 25°CSolid

Valence Electrons2 (d-block, variable in compounds)

Electron Config (Noble)[Xe] 6s2 4f14 5d5

75ReRhenium186.21

Tap related elements to compare trends across group and period.

Navigate neighbors← W Os →

Physical Properties

How this element behaves in real-world conditions.

State (25°C): Solid
Density: 21.02 g/cm³
Melting Point: 3186 °C
Boiling Point: 5596 °C

Atomic Structure

Core identity and periodic table positioning.

Atomic Number: 75
Atomic Weight: 186.21
Atomic Radius: 217 pm
Block: D
Group: 7
Period: 6

Electromagnetic Properties

How this element attracts and exchanges electrons.

Electronegativity: 1.9
Ionization Energy: 7.88 eV
Electron Affinity: 0.15 eV
Metallic Character: Metal

Hero / Identity Section

Core identity profile for Rhenium with periodic placement and electron context.

Element Name: Rhenium
Symbol: Re
Atomic Number: 75
Atomic Mass: 186.21
Group: 7
Period: 6
Block: D
Category: Transition
Standard State: Solid
Electron Configuration (Full): 1s2 2s2 2p6 3s2 3p6 4s2 3d10 4p6 5s2 4d10 5p6 6s2 4f14 5d5
Electron Configuration (Noble Gas): [Xe] 6s2 4f14 5d5
Valence Electrons: 2 (d-block, variable in compounds)

Quick Facts Card (Table Layout)

Fast-reference values for physical and energetic properties.

Atomic Radius

217 pm

Ionic Radius

Not available in current dataset

Electronegativity (Pauling)

1.9

1st Ionization Energy

7.88 eV

Electron Affinity

0.15 eV

Density

21.02 g/cm³

Melting Point

3,186 °C

Boiling Point

5,596 °C

Heat Capacity

Not available in current dataset

Thermal Conductivity

Not available in current dataset

Visual Components

Visual learning views for table position, shells, orbitals, and phase behavior.

Highlighted Position in Periodic Table Grid

Row 6, Column 7

Bohr Model Diagram

Educational shell model for electron arrangement.

Electron Shell Diagram

K shell2
L shell8
M shell18
N shell32
O shell13
P shell2

Orbital Configuration Diagram

1s2/2

2s2/2

2p6/6

3s2/2

3p6/6

4s2/2

3d10/10

4p6/6

5s2/2

4d10/10

5p6/6

6s2/2

4f14/14

5d5/10

Phase Illustration

Solid

Solid lattice

Atomic Structure Section

Nuclear composition and electron shielding interpretation.

Protons: 75
Neutrons (Most Abundant Isotope Estimate): 111
Electrons: 75
Electron Configuration Breakdown: 2 • 8 • 18 • 32 • 13 • 2
Shielding Explanation: Core electrons (~73) shield part of the nucleus, reducing attraction felt by outer electrons compared with the full nuclear charge.
Effective Nuclear Charge (Estimate): 2

Chemical Properties Section

Category-guided chemistry behavior with periodic context for comparison.

Common Oxidation States: Variable (often +2, +3, and higher/lower states depending on element)
Reactivity Summary: Moderate to broad reactivity range with strong dependence on oxidation state and ligands.
Acid/Base Behavior: Many oxides/hydroxides are amphoteric or weakly basic; behavior varies by element/state.
Bonding Behavior: Displays metallic, ionic, and coordination (complex) bonding patterns.
Typical Compounds: Oxides, Halides, Coordination complexes
Periodic Trend Comparison (Group Neighbors): Compared with Tc, this element is lower in the group and typically has a larger atomic size and lower ionization tendency. Compared with Bh, this element is higher in the group and often shows a smaller radius with stronger effective attraction to valence electrons.

Isotopes & Nuclear Data

Isotope stability and abundance notes for learning-oriented nuclear context.

Stable Isotopes: Stable isotopes are known. Most abundant isotope is commonly represented near Re-186.
Radioactive Isotopes: Radioactive isotopes exist alongside stable isotopes.
Natural Abundance (%): Naturally occurring with isotope-dependent abundance.
Half-life (If Applicable): Stable isotopes have no half-life; radioactive isotopes have isotope-specific half-lives.
Nuclear Spin (Optional Advanced): Advanced isotope-level data is not included in the current core dataset.
Most Abundant Isotope (Estimate): Re-186

Applications & Uses

How this element appears in industry, biology, medicine, and technology.

Industrial Uses: Core materials for catalysts, alloys, structural metals, and chemical manufacturing.
Biological Role: Several transition metals are essential trace nutrients; excess can be toxic.
Medical Use: Used in diagnostics, implants, imaging agents, and therapeutic complexes.
Technological Relevance: Critical for electronics, catalysis, batteries, magnets, and manufacturing.
Environmental Impact: Can persist and bioaccumulate depending on element and oxidation state.

Safety & Handling

General hazard guidance for educational reference and lab awareness.

Toxicity: Toxicity spans low to high and is oxidation-state dependent; monitor exposure carefully.
Flammability: Bulk metals are generally low flammability; powders may be combustible.
Storage Considerations: Store according to specific oxidation state/compound hazards; avoid incompatible reagents.
Regulatory Classification: Often regulated by occupational exposure limits and compound-specific hazard classes.