Iron: Difference between revisions
imported>Mark Widmer (Opening paragraph revised to new standard: Phase, symbol, atomic no., and std. atomic weight. Clarified that abundance refers to within Earth's crust.) |
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Pure iron is a grayish metal, lustrous, hard and brittle. It rusts (oxidizes) easily in moist air. It is attracted by a magnet and can become magnetized (is [[ferromagnetic]]). Iron is the fourth most abundant element in Earth's crust, comprising 5% of the crust. Pure iron is rare in nature, but its oxides, iron ores, are widely distributed. | Pure iron is a grayish metal, lustrous, hard and brittle. It rusts (oxidizes) easily in moist air. It is attracted by a magnet and can become magnetized (is [[ferromagnetic]]). Iron is the fourth most abundant element in Earth's crust, comprising 5% of the crust. Pure iron is rare in nature, but its oxides, iron ores, are widely distributed. | ||
Iron is prepared industrially in [[blast furnace]]s. In a blast furnace, iron ore and coke (degassed coal, which is pure carbon) are fed into the top of the furnace, while air, containing oxygen, is forced into the furnace at the bottom. In the furnace the coke reacts with oxygen: | Iron is prepared industrially in [[blast furnace]]s. In a blast furnace, iron ore and [[coke (fuel)|coke]] (degassed coal, which is pure carbon) are fed into the top of the furnace, while air, containing oxygen, is forced into the furnace at the bottom. In the furnace the coke reacts with oxygen: | ||
: 2 C + O<sub>2</sub> → 2 CO | : 2 C + O<sub>2</sub> → 2 CO | ||
The carbon monoxide (CO) reduces the iron oxide in the ore, giving pure iron: | The carbon monoxide (CO) reduces the iron oxide in the ore, giving pure iron: | ||
: 3 CO + Fe<sub>2</sub>O<sub>3</sub> → 2 Fe + 3 CO<sub>2</sub> | : 3 CO + Fe<sub>2</sub>O<sub>3</sub> → 2 Fe + 3 CO<sub>2</sub> | ||
At the temperature of this process the iron is molten and flows to the bottom of the furnace where it is drained off. The resulting iron is [[pig iron]], characterized by a relatively high (3-4%) carbon content. | At the temperature of this process the iron is molten and flows to the bottom of the furnace where it is drained off. The resulting iron is [[pig iron]], characterized by a relatively high (3-4%) carbon content.[[Category:Suggestion Bot Tag]] |
Latest revision as of 06:00, 3 September 2024
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Iron is a chemical element, typically found as a solid in its elemental form. It has the chemical symbol Fe (from the Latin ferrum), atomic number (number of protons) Z = 26, and a standard atomic weight of 55.845 g/mol.
Pure iron is a grayish metal, lustrous, hard and brittle. It rusts (oxidizes) easily in moist air. It is attracted by a magnet and can become magnetized (is ferromagnetic). Iron is the fourth most abundant element in Earth's crust, comprising 5% of the crust. Pure iron is rare in nature, but its oxides, iron ores, are widely distributed.
Iron is prepared industrially in blast furnaces. In a blast furnace, iron ore and coke (degassed coal, which is pure carbon) are fed into the top of the furnace, while air, containing oxygen, is forced into the furnace at the bottom. In the furnace the coke reacts with oxygen:
- 2 C + O2 → 2 CO
The carbon monoxide (CO) reduces the iron oxide in the ore, giving pure iron:
- 3 CO + Fe2O3 → 2 Fe + 3 CO2
At the temperature of this process the iron is molten and flows to the bottom of the furnace where it is drained off. The resulting iron is pig iron, characterized by a relatively high (3-4%) carbon content.