Nickel
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| Chemical formula | Ni |
|---|---|
| Atomic Number | 28 |
| OTP appearance | silver solid |
| Molar Mass(g/mol) | 58.7 |
| Density(g/cc) | 8.9 |
| Melting Point(°C) | 1455 |
| Boiling Point(°C) | 2730 |
| Coefficient of Thermal Expansion(×10-6 °C-1) | 13.3 |
| NFPA 704 |  4
2
1
|
Uses
Primary
- Production of Urushibara nickel catalysts
- As a primary component in many steels
Secondary
- As an alloy with chrome (nichrome) for electrical heating elements
- -carbonyl can be used to nickel-plate metals
Natural Occurrence
- Elemental nickel occurs in meteorites, but rarely.
- -sulfide in pentlandite
- minority constituent (1-3%) goethite
Hazards
- -carbonyl is toxic
- Many nickel salts are carcinogenic
Production
Extraction
Elemental Nickel
- from -sulfide via calcining and carbothermic reduction
- 2 NiS + 3 O2 → NiO + 2 SO2
- NiO + C → Ni + CO
Purification
Typically, Nickel occurs with problematic amounts of iron and/or cobalt.
- Repeat
- Treat powdered impure nickel oxides with hydrogen at 200°C to reduce the oxides to nickel.
- NiO(s) + H2(g) → Ni(s) + H2O(v)
- Expose the impure metal to carbon monoxide forming -carbonyl gas
- FeCoNi(s) + 4 CO(g){Ni(CO)4(g) + FeCo(s)60-220°C}→
- FeCoNi(s) + 4 CO(g)
- Separate the -carbonyl gas from the solid impurities
- Decompose the -carbonyl at 250°C, leaving carbon monoxide to be reused
- Ni(CO)4(g){Ni(s) + 4 CO(g)≥250°C}→
- Ni(CO)4(g)
- Treat powdered impure nickel oxides with hydrogen at 200°C to reduce the oxides to nickel.
- Until the powder is no longer yielding -carbonyl