Hydrogen astatide
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| Identifiers | |||
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| 3D model (Jmol) | Interactive image | ||
| ChEBI | CHEBI:30418  | ||
| ChemSpider | 22432 | ||
| 532398 | |||
| PubChem | 23996 | ||
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| Properties | |||
| AtH | |||
| Molar mass | 211.01 g·mol−1 | ||
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| Other anions |
Hydrogen bromide | ||
| Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa). | |||
verify (what is  ?) | |||
| Infobox references | |||
Hydrogen astatide, also known as astatine hydride, astatane, or astidohydrogen, is a chemical compound with the chemical formula HAt, consisting of an astatine atom covalently bonded to a hydrogen atom.[1] It thus is a hydrogen halide.
This chemical compound can dissolve in water to form hydroastatic acid, which exhibits properties very similar to the other four binary acids, and is in fact the strongest among them. However, it is limited in use due to its ready decomposition into elemental hydrogen and astatine,[2] as well as the short half-life of the various isotopes of astatine. Because the atoms have a nearly equal electronegativity, and as the At+ ion has been observed,[3] dissociation could easily result in the hydrogen carrying the negative charge. Thus, a hydrogen astatide sample can undergo the following reaction:
- 2 HAt → H+ + At− + H− + At+ → H2 + At2
This results in elemental hydrogen gas and astatine precipitate. Further, a trend for hydrogen halides, or HX, is that enthalpy of formation lowers as the period increases for the halide. Whereas hydroiodic acid solutions are stable, the hydronium-astatide solution is clearly less stable than the water-hydrogen-astatine system. Finally, radiolysis from astatine nuclei could sever the H-At bonds.
Additionally, astatine has no stable isotopes. The most stable is astatine-210, which has a half-life of approximately 8.1 hours, making its chemical compounds especially difficult to work with,[4] as the astatine will quickly decay into other elements.
References
- ↑ PubChem, "astatane - Compound Summary", accessed July 3, 2009.
- ↑ Fairbrother, Peter, "Re: Is hydroastatic acid possible?", accessed July 3, 2009.
- ↑ Advances in Inorganic Chemistry, Volume 6 by Emeleus, p.219, Academic Press, 1964 ISBN 0-12-023606-0
- ↑ Gagnon, Steve, "It's Elemental", accessed July 3, 2009.
| Alkali metal hydrides |  Lithium hydride, LiH ionic metal hydride   Beryllium hydride Left (gas phase): BeH2 covalent metal hydride Right: (BeH2)n (solid phase) polymeric metal hydride   Borane and diborane Left: BH3 (special conditions), covalent metalloid hydride Right: B2H6 (standard conditions), dimeric metalloid hydride  Methane, CH4 covalent nonmetal hydride  Ammonia, NH3 covalent nonmetal hydride  Water, H2O covalent nonmetal hydride  Hydrogen fluoride, HF covalent nonmetal hydride | ||||||||||||||||||
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| Alkaline earth hydrides |
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| Group 13 hydrides |
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| Group 14 hydrides |
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| Pnictogen hydrides |
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| Hydrogen chalcogenides |
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| Hydrogen halides | |||||||||||||||||||
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| Lanthanide hydrides |
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| Actinide hydrides |
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