polonium trioxide
{{short description|Chemical compound}}
{{Chembox
| SystematicName = Polonium trioxide
|Section1 = {{Chembox Identifiers
| CASNo = 12143-28-1
| CASNo_Ref = {{cascite|correct|CAS}}
}}
|Section2 = {{Chembox Properties
| Formula = PoO3
| MolarMass = 256.98 g/mol
}}
}}
Polonium trioxide (also known as polonium(VI) oxide) is a chemical compound with the formula PoO3. It is one of three oxides of polonium, the other two being polonium monoxide (PoO) and polonium dioxide (PoO2). It is an interchalcogen that has so far only been detected in trace amounts.{{Holleman&Wiberg|page=594}}{{cite book |title=Advances in Inorganic Chemistry and Radiochemistry |chapter=The Chemistry of Polonium |last1=Bagnall |first1=K. W. |year=1962 |publisher=Academic Press |location=New York |isbn=9780120236046 |pages=197–230 |accessdate=June 14, 2012 |url=https://books.google.com/books?id=8qePsa3V8GQC}}
Preparation
It has been reported that trace quantities of polonium trioxide form during the anodic deposition of polonium from acidic solutions. Although there is no experimental evidence for this, the fact that the deposit dissolves in hydrogen peroxide suggests that it contains polonium in a high oxidation state. It has been predicted that polonium trioxide may be formed by heating polonium dioxide and chromium trioxide together in air.
=Difficulty of preparation of polonium(VI) compounds=
It is very difficult to oxidize polonium beyond Po(IV); for example, the only hexahalide of polonium is the hexafluoride, PoF6, and fluorine is already the most electronegative element (though polonium hexaiodide was once reportedly formed in the vapour phase, it immediately decomposed).{{cite book |last1=Thayer |first1=John S. |title=Relativistic Methods for Chemists |chapter=Relativistic Effects and the Chemistry of the Heavier Main Group Elements |series=Challenges and Advances in Computational Chemistry and Physics |year=2010 |volume=10 |page=78 |doi=10.1007/978-1-4020-9975-5_2|isbn=978-1-4020-9974-8 }} However, the difficulty in obtaining polonium trioxide and polonates (containing the {{chem|PoO|4|2-}} anion, analogous to sulfate, selenate, and tellurate) by direct oxidation of Po(IV) compounds may be due to the fact that polonium-210, while the most easily available isotope of polonium, is strongly radioactive. Similar work with curium shows that it is easier to achieve higher oxidation states with longer-lived isotopes; thus, it may be easier to obtain Po(VI) (especially polonium trioxide) using the longer-lived polonium-208 or polonium-209. It has been suggested that Po(VI) might be more stabilized in anions such as {{chem|PoF|8|2-}} or {{chem|PoO|6|6-}}, like other high oxidation states.
References
{{reflist}}
{{Polonium compounds}}