Editing Chlorine (section)

=== Chlorine oxides ===
[[File:Chlorine dioxide gas and solution.jpg|thumb|right|Yellow [[chlorine dioxide]] (ClO<sub>2</sub>) gas above a solution of hydrochloric acid and sodium chlorite in water, also containing dissolved chlorine dioxide]]
[[File:Dichlorine-heptoxide-3D-balls.png|thumb|right|Structure of [[dichlorine heptoxide]], Cl<sub>2</sub>O<sub>7</sub>, the most stable of the chlorine oxides]]
The [[chlorine oxide]]s are well-studied in spite of their instability (all of them are endothermic compounds). They are important because they are produced when [[chlorofluorocarbon]]s undergo photolysis in the upper atmosphere and cause the destruction of the ozone layer. None of them can be made from directly reacting the elements.<ref name="Greenwood844">{{harvnb|Greenwood|Earnshaw|1997|pp=844–850}}</ref>

[[Dichlorine monoxide]] (Cl<sub>2</sub>O) is a brownish-yellow gas (red-brown when solid or liquid) which may be obtained by reacting chlorine gas with yellow [[mercury(II) oxide]]. It is very soluble in water, in which it is in equilibrium with [[hypochlorous acid]] (HOCl), of which it is the anhydride. It is thus an effective bleach and is mostly used to make [[hypochlorite]]s. It explodes on heating or sparking or in the presence of ammonia gas.<ref name="Greenwood844" />

[[Chlorine dioxide]] (ClO<sub>2</sub>) was the first chlorine oxide to be discovered in 1811 by [[Humphry Davy]]. It is a yellow paramagnetic gas (deep-red as a solid or liquid), as expected from its having an odd number of electrons: it is stable towards dimerisation due to the delocalisation of the unpaired electron. It explodes above −40&nbsp;°C as a liquid and under pressure as a gas and therefore must be made at low concentrations for wood-pulp bleaching and water treatment. It is usually prepared by reducing a [[chlorate]] as follows:<ref name="Greenwood844" />
:{{chem|ClO|3|-}} + Cl<sup>−</sup> + 2 H<sup>+</sup> ⟶ ClO<sub>2</sub> + {{sfrac|1|2}} Cl<sub>2</sub> + H<sub>2</sub>O
Its production is thus intimately linked to the redox reactions of the chlorine oxoacids. It is a strong oxidising agent, reacting with [[sulfur]], [[phosphorus]], phosphorus halides, and [[potassium borohydride]]. It dissolves exothermically in water to form dark-green solutions that very slowly decompose in the dark. Crystalline clathrate hydrates ClO<sub>2</sub>·''n''H<sub>2</sub>O (''n'' ≈ 6–10) separate out at low temperatures. However, in the presence of light, these solutions rapidly photodecompose to form a mixture of chloric and hydrochloric acids. Photolysis of individual ClO<sub>2</sub> molecules result in the radicals ClO and ClOO, while at room temperature mostly chlorine, oxygen, and some ClO<sub>3</sub> and Cl<sub>2</sub>O<sub>6</sub> are produced. Cl<sub>2</sub>O<sub>3</sub> is also produced when photolysing the solid at −78&nbsp;°C: it is a dark brown solid that explodes below 0&nbsp;°C. The ClO radical leads to the depletion of atmospheric ozone and is thus environmentally important as follows:<ref name="Greenwood844" />
:Cl• + O<sub>3</sub> ⟶ ClO• + O<sub>2</sub>
:ClO• + O• ⟶ Cl• + O<sub>2</sub>

[[Chlorine perchlorate]] (ClOClO<sub>3</sub>) is a pale yellow liquid that is less stable than ClO<sub>2</sub> and decomposes at room temperature to form chlorine, oxygen, and [[dichlorine hexoxide]] (Cl<sub>2</sub>O<sub>6</sub>).<ref name="Greenwood844" /> Chlorine perchlorate may also be considered a chlorine derivative of [[perchloric acid]] (HOClO<sub>3</sub>), similar to the thermally unstable chlorine derivatives of other oxoacids: examples include [[chlorine nitrate]] (ClONO<sub>2</sub>, vigorously reactive and explosive), and chlorine fluorosulfate (ClOSO<sub>2</sub>F, more stable but still moisture-sensitive and highly reactive).<ref name="Greenwood883">{{harvnb|Greenwood|Earnshaw|1997|pp=883–885}}</ref> Dichlorine hexoxide is a dark-red liquid that freezes to form a solid which turns yellow at −180&thinsp;°C: it is usually made by reaction of chlorine dioxide with oxygen. Despite attempts to rationalise it as the dimer of ClO<sub>3</sub>, it reacts more as though it were chloryl perchlorate, [ClO<sub>2</sub>]<sup>+</sup>[ClO<sub>4</sub>]<sup>−</sup>, which has been confirmed to be the correct structure of the solid. It hydrolyses in water to give a mixture of chloric and perchloric acids: the analogous reaction with anhydrous [[hydrogen fluoride]] does not proceed to completion.<ref name="Greenwood844" />

[[Dichlorine heptoxide]] (Cl<sub>2</sub>O<sub>7</sub>) is the anhydride of [[perchloric acid]] (HClO<sub>4</sub>) and can readily be obtained from it by dehydrating it with [[phosphoric acid]] at −10&nbsp;°C and then distilling the product at −35&nbsp;°C and 1&nbsp;mmHg. It is a shock-sensitive, colourless oily liquid. It is the least reactive of the chlorine oxides, being the only one to not set organic materials on fire at room temperature. It may be dissolved in water to regenerate perchloric acid or in aqueous alkalis to regenerate perchlorates. However, it thermally decomposes explosively by breaking one of the central Cl–O bonds, producing the radicals ClO<sub>3</sub> and ClO<sub>4</sub> which immediately decompose to the elements through intermediate oxides.<ref name="Greenwood844" />