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Chlorine and oxygen can bond in a number of ways: chlorine monoxide radical, ClO•, chlorine (II) oxide radical; chloroperoxyl radical, ClOO•, chlorine (II) peroxide radical; chlorine dioxide, ClO 2, chlorine (IV) oxide; chlorine trioxide radical, ClO 3 •, chlorine (VI) oxide radical; chlorine tetroxide radical, ClO 4 •, chlorine (VII ...
Chlorine dioxide is a chemical compound with the formula ClO 2 that exists as yellowish-green gas above 11 °C, a reddish-brown liquid between 11 °C and −59 °C, and as bright orange crystals below −59 °C. It is usually handled as an aqueous solution.
[1] [2] [3] Introduced by Gilbert N. Lewis in his 1916 article The Atom and the Molecule, a Lewis structure can be drawn for any covalently bonded molecule, as well as coordination compounds. [4] Lewis structures extend the concept of the electron dot diagram by adding lines between atoms to represent shared pairs in a chemical bond.
English: Chlorine_dioxide.png new as SVG and with angle/bondlength. Note: This is more or less the structure given by Pauling on page 264 of his General Chemisty, although he puts three dots between the left-hand oxygen and the chlorine, as well as a line segment, instead of two line segments and a dot on the chlorine as we have here.
The structure of dichlorine monoxide is similar to that of water and hypochlorous acid, with the molecule adopting a bent molecular geometry (due to the lone pairs on the oxygen atom) and resulting in C 2V molecular symmetry. The bond angle is slightly larger than normal, likely due to steric repulsion between the bulky chlorine atoms.
Yellow chlorine dioxide (ClO 2) gas above a solution of hydrochloric acid and sodium chlorite in water, also containing dissolved chlorine dioxide Structure of dichlorine heptoxide, Cl 2 O 7, the most stable of the chlorine oxides. The chlorine oxides are well-studied in spite of their instability (all of them are endothermic compounds).
The chlorite ion adopts a bent molecular geometry, due to the effects of the lone pairs on the chlorine atom, with an O–Cl–O bond angle of 111° and Cl–O bond lengths of 156 pm. [1] Chlorite is the strongest oxidiser of the chlorine oxyanions on the basis of standard half cell potentials.
Dichlorine heptoxide is a covalent compound consisting of two ClO 3 portions linked by an oxygen atom. It has an overall bent molecular geometry (C 2 symmetry ), with a Cl−O−Cl angle of 118.6°. The chlorine–oxygen bond lengths are 1.709 Å in the central region and 1.405 Å within each ClO 3 cluster. [ 1 ]