Английская Википедия:Iron(III) oxide-hydroxide

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Шаблон:Short description Шаблон:Chembox

Iron(III) oxide-hydroxide or ferric oxyhydroxide[1] is the chemical compound of iron, oxygen, and hydrogen with formula Шаблон:Chem.

The compound is often encountered as one of its hydrates, Шаблон:Chem·n[[Water|Шаблон:Chem]] [rust]. The monohydrate Шаблон:Chem·Шаблон:Chem is often referred to as iron(III) hydroxide Шаблон:Chem,[2] hydrated iron oxide, yellow iron oxide, or Pigment Yellow 42.[2]

Natural occurrences

Minerals

Anhydrous ferric hydroxide occurs in the nature as the exceedingly rare mineral bernalite, Fe(OH)3·nH2O (n = 0.0–0.25).[3][4] Iron oxyhydroxides, Шаблон:Chem, are much more common and occur naturally as structurally different minerals (polymorphs) denoted by the Greek letters α, β, γ and δ.

  • Goethite, α-FeO(OH), has been used as an ochre pigment since prehistoric times.
  • Akaganeite is the β polymorph,[5] formed by weathering and noted for its presence in some meteorites and the lunar surface. However, recently it has been determined that it must contain some chloride ions to stabilize its structure, so that its more accurate formula is Шаблон:Chem or Шаблон:Chem.[6]
  • Lepidocrocite, the γ polymorph, is commonly encountered as rust on the inside of steel water pipes and tanks.
  • Feroxyhyte (δ) is formed under the high pressure conditions of sea and ocean floors, being thermodynamically unstable with respect to the α polymorph (goethite) at surface conditions.

Non-mineral

Goethite and lepidocrocite, both crystallizing in orthorhombic system, are the most common forms of iron(III) oxyhydroxide and the most important mineral carriers of iron in soils.

Mineraloids

Iron(III) oxyhydroxide is the main component of other minerals and mineraloids:

Properties

The color of iron(III) oxyhydroxide ranges from yellow through dark-brown to black, depending on the degree of hydration, particle size and shape, and crystal structure.

Structure

The crystal structure of β-Шаблон:Chem (akaganeite) is that of hollandite or Шаблон:Chem. The unit cell is tetragonal with a = 1.048 and c = 0.3023 nm, and contains eight formula units of FeOOH. Its dimensions are about 500 × 50 × 50 nm. Twinning often produces particles with the shape of hexagonal stars. [1]

Chemistry

On heating, β-Шаблон:Chem decomposes and recrystallizes as α-Шаблон:Chem (hematite).[1]

Uses

Limonite, a mixture of various hydrates and polymorphs of ferric oxyhydroxide, is one of the three major iron ores, having been used since at least 2500 BC.[7][8]

Yellow iron oxide, or Pigment Yellow 42, is Food and Drug Administration (FDA) approved for use in cosmetics and is used in some tattoo inks.

Iron oxide-hydroxide is also used in aquarium water treatment as a phosphate binder.[9]

Iron oxide-hydroxide nanoparticles have been studied as possible adsorbents for lead removal from aquatic media.[10]

Medication

Iron polymaltose is used in treatment of iron-deficiency anemia.

Production

Iron(III) oxyhydroxide precipitates from solutions of iron(III) salts at pH between 6.5 and 8.[11] Thus the oxyhydroxide can be obtained in the lab by reacting an iron(III) salt, such as ferric chloride or ferric nitrate, with sodium hydroxide:[12]

Шаблон:Chem + 3 NaOH → Шаблон:Chem + 3 NaCl
Шаблон:Chem + 3 NaOH → Шаблон:Chem + 3 Шаблон:Chem

In fact, when dissolved in water, pure Шаблон:Chem will hydrolyze to some extent, yielding the oxyhydroxide and making the solution acidic:[11]

Шаблон:Chem + 2 Шаблон:ChemШаблон:Chem + 3 Шаблон:Chem

Therefore, the compound can also be obtained by the decomposition of acidic solutions of iron(III) chloride held near the boiling point for days or weeks:[13]

Шаблон:Chem + 2 Шаблон:ChemШаблон:Chem(s) + 3 Шаблон:Chem(g)

(The same process applied to iron(III) nitrate Шаблон:Chem or perchlorate Шаблон:Chem solutions yields instead particles of α-Шаблон:Chem.[13])

Another similar route is the decomposition of iron(III) nitrate dissolved in stearic acid at about 120 °C.[14]

The oxyhydroxide prepared from ferric chloride is usually the β polymorph (akaganeite), often in the form of thin needles.[13][15]

The oxyhydroxide can also be produced by a solid-state transformation from iron(II) chloride tetrahydrate Шаблон:Chem·4Шаблон:Chem.[5]

The compound also readily forms when iron(II) hydroxide is exposed to air:

4Шаблон:Chem + Шаблон:Chem → 4 Шаблон:Chem + 2 Шаблон:Chem

The iron(II) hydroxide can also be oxidized by hydrogen peroxide in the presence of an acid:

2Шаблон:Chem + Шаблон:Chem → 2 Шаблон:Chem

See also

References

Шаблон:Reflist

Шаблон:Iron compounds Шаблон:Antianemic preparations

Партнерские ресурсы
Криптовалюты
Магазины
Хостинг
Разное

  1. 1,0 1,1 1,2 A. L. Mackay (1960): "β-Ferric Oxyhydroxide". Mineralogical Magazine (Journal of the Mineralogical Society), volume 32, issue 250, pages 545-557. Шаблон:Doi
  2. 2,0 2,1 CAS Шаблон:CASREF, C.I. 77492
  3. Шаблон:Cite web
  4. Шаблон:Cite web
  5. 5,0 5,1 A. L. Mackay (1962): "β-Ferric oxyhydroxide—akaganéite", Mineralogical Magazine (Journal of the Mineralogical Society), volume 33, issue 259, pages 270-280 Шаблон:Doi
  6. C. Rémazeilles and Ph. Refait (2007): "On the formation of β-FeOOH (akaganéite) in chloride-containing environments". Corrosion Science, volume 49, issue 2, pages 844-857. Шаблон:Doi
  7. MacEachern, Scott (1996): "Iron Age beginnings north of the Mandara Mountains, Cameroon and Nigeria". In In Pwiti, Gilbert and Soper, Robert (editors) (1996) Aspects of African Archaeology: Proceedings of the Tenth Pan-African Congress University of Zimbabwe Press, Harare, Zimbabwe, Шаблон:ISBN, pages 489-496. Archived here on 2012-03-11.
  8. Diop-Maes, Louise Marie (1996): "La question de l'Âge du fer en Afrique" ("The question of the Iron Age in Africa"). Ankh, volume4/5, pages 278-303. Archived on 2008-01-25.
  9. Шаблон:URL
  10. Safoora Rahimi, Rozita M. Moattari, Laleh Rajabi, Ali Ashraf Derakhshan, and Mohammad Keyhani (2015): "Iron oxide/hydroxide (α,γ-FeOOH) nanoparticles as high potential adsorbents for lead removal from polluted aquatic media". Journal of Industrial and Engineering Chemistry, volume 23, pages 33-43. Шаблон:Doi
  11. 11,0 11,1 Tim Grundl and Jim Delwiche (1993): "Kinetics of ferric oxyhydroxide precipitation". Journal of Contaminant Hydrology, volume 14, issue 1, pages 71-87. Шаблон:Doi
  12. K. H. Gayer and Leo Woontner (1956): "The Solubility of Ferrous Hydroxide and Ferric Hydroxide in Acidic and Basic Media at 25°". Journal of Physical Chemistry, volume 60, issue 11, pages 1569–1571. Шаблон:Doi
  13. 13,0 13,1 13,2 Egon Matijević and Paul Scheiner (1978): "Ferric hydrous oxide sols: III. Preparation of uniform particles by hydrolysis of Fe(III)-chloride, -nitrate, and -perchlorate solutions". Journal of Colloid and Interface Science, volume 63, issue 3, pages 509-524. Шаблон:Doi
  14. Dan Li, Xiaohui Wang, Gang Xiong, Lude Lu, Xujie Yang and Xin Wang (1997): "A novel technique to prepare ultrafine Шаблон:Chem via hydrated iron(III) nitrate". Journal of Materials Science Letters volume 16, pages 493–495 Шаблон:Doi
  15. Donald O. Whittemore and Donald Langmuir (1974): "Ferric Oxyhydroxide Microparticles in Water". Environmental Health Perspective, volume 9, pages 173-176. Шаблон:Doi
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