pnictogen hydride

{{multiple image|align=right|direction=vertical|width=105|image1=Ammonia-3D-balls-A.png|image2=Phosphine-3D-balls.png|image3=Arsine-3D-balls.png|caption3=Ammonia, phosphine, and arsine, three simple pnictogen hydrides}}Pnictogen hydrides or hydrogen pnictides are binary compounds of hydrogen with pnictogen ({{IPAc-en|ˈ|p|n|ɪ|k|t|ə|dʒ|ə|n}} or {{IPAc-en|ˈ|n|ɪ|k|t|ə|dʒ|ə|n}}; from {{langx|grc|πνῑ́γω}} "to choke" and -gen, "generator") atoms (elements of group 15: nitrogen, phosphorus, arsenic, antimony, bismuth, and moscovium) covalently bonded to hydrogen.

Pnictogen trihydrides

The simplest series has the chemical formula XH₃ (less commonly H₃X), with X representing any of the pnictogens. They take on the pyramidal structure (as opposed to the trigonal planar arrangement of the group 13 hydrides), and therefore are polar. These pnictogen trihydrides are generally increasingly unstable and poisonous with heavier elements.

class="wikitable" style="margin: 1em auto 1em auto; text-align: center;" ! scope="col" \| Compound names ! scope="col" \| Chemical formula ! scope="col" \| Geometry ! scope="col" \| Space-filling model
nitrogen hydride hydrogen nitride ammonia (azane)	{{chem2\|NH3}}	90px	100px
phosphorus hydride hydrogen phosphide phosphine (phosphane)	{{chem2\|PH3}}	90px	90px
arsenic hydride hydrogen arsenide arsine (arsane)	{{chem2\|AsH3}}	90px	85px
antimony hydride hydrogen antimonide stibine (stibane)	{{chem2\|SbH3}}	90px	84px
bismuth hydride hydrogen bismuthide bismuthine (bismuthane)	{{chem2\|BiH3}}	90px	File:Bismuthine-3D-vdW.png
moscovium hydride hydrogen moscovide moscovine (moscovane)	{{chem2\|McH3}}

Some properties of the pnictogen trihydrides follow:

class="wikitable" style="margin: 1em auto 1em auto"
scope="col" \| Property ! scope="col" \| {{chem2\|NH3}} ! scope="col" \| {{chem2\|PH3}} ! scope="col" \| {{chem2\|AsH3}} ! scope="col" \| {{chem2\|SbH3}} ! scope="col" \| {{chem2\|BiH3}}
scope="row" \| Melting point (°C) \| −77.8 \| −133.5 \| −116.3 \| −88 \| ?
scope="row" \| Boiling point (°C) \| −34.5 \| −87.5 \| −62.4 \| −18.4 \| 16.8 (extrapolated)
scope="row" \| Liquid density (g/cm³) \| 0.683 (−34 °C) \| 0.746 (−90 °C) \| 1.640 (−64 °C) \| 2.204 (−18 °C) \| ?
scope="row" \| ΔH{{su\|p=°\|b=f}}/kJ mol⁻¹ \| −46.1 \| +5{{cite book\| last= Zumdahl \|first=Steven S.\|title =Chemical Principles \|edition=6th \| publisher = Houghton Mifflin \| year = 2009\| isbn = 978-0-618-94690-7\|page=A22}} \| +66.4 \| +145.1 \| +277.8
scope="row" \| Distance (X–H)/pm \| 101.7 \| 141.9 \| 151.9 \| 170.7 \| 177.59
scope="row" \| Angle H–X–H \| 107.8° \| 93.6° \| 91.8° \| 91.3° \| 90.48°

class="wikitable" style="margin: 1em auto 1em auto"

scope="col" | Property

! scope="col" | {{chem2|NH3}}

! scope="col" | {{chem2|PH3}}

! scope="col" | {{chem2|AsH3}}

! scope="col" | {{chem2|SbH3}}

! scope="col" | {{chem2|BiH3}}

scope="row" | Melting point (°C)

| −77.8

| −133.5

| −116.3

| −88

| ?

scope="row" | Boiling point (°C)

| −34.5

| −87.5

| −62.4

| −18.4

| 16.8 (extrapolated)

scope="row" | Liquid density (g/cm³)

| 0.683 (−34 °C)

| 0.746 (−90 °C)

| 1.640 (−64 °C)

| 2.204 (−18 °C)

| ?

scope="row" | ΔH{{su|p=°|b=f}}/kJ mol⁻¹

| −46.1

| +5{{cite book| last= Zumdahl |first=Steven S.|title =Chemical Principles |edition=6th | publisher = Houghton Mifflin | year = 2009| isbn = 978-0-618-94690-7|page=A22}}

| +66.4

| +145.1

| +277.8

scope="row" | Distance (X–H)/pm

| 101.7

| 141.9

| 151.9

| 170.7

| 177.59

scope="row" | Angle H–X–H

| 107.8°

| 93.6°

| 91.8°

| 91.3°

| 90.48°

These gases have no smell in pure form, instead gaining it when in contact with air. Ammonia has an infamous, intense odour resembling urine and/or fish, commonly the result of the decomposition of urea. Phosphine smells like fish or garlic, and stibine like rotten eggs, similar to hydrogen sulfide and selenide.

Dipnictogen tetrahydrides

Dipnictogen tetrahydrides have the chemical formula {{chem2|X2H4}}. These are generally less stable than the trihydrides, commonly decomposing to the trihydride and the pnictogen involved.

class="wikitable" style="margin: 1em auto 1em auto; text-align: center;" ! scope="col" \| Compound names ! scope="col" \| Chemical formula ! scope="col" \| Geometry ! scope="col" \| Space-filling model
dinitrogen hydride hydrazine (diazane)	N₂H₄	90px	100px
diphosphorus hydride diphosphine (diphosphane)	P₂H₄	90px	100px
diarsenic hydride diarsine (diarsane)	As₂H₄	File:Diarsin.png	File:Diarsine-3D-vdW.png

Higher derivatives

Polyphosphanes exist with the formula P_nH_n+2 (n = 1–9). Linear and branch isomers of {{chem2|P4H6}} have been detected. Other cyclic and condensed polyphosphane series are known, from P_nH_n to P_nH_n−18, amounting to 85 known phosphanes in 1997.Greenwood and Earnshaw, pp. 492–3

Properties

Noncyclic hydrogen pnictides follow the formula X_nH_n+2.

{{multiple image|align=right|direction=vertical|width=150|image1=Triphosphane-3D-spacefill.png|image2=Tetraphosphane-3D-spacefill.png|caption2=Models of phosphanes of lengths 3 and 4}}

Ammonia is produced industrially on the largest scale among all compounds. Like water, hydrogen bonding results in a high melting and boiling point compared to the other pnictogen hydrides, although 26% is lost on melting, another 7% as the liquid is heated to boiling, and the remaining 67% upon boiling. Other effects of hydrogen bonding are a high dielectric constant as well as low values of density, viscosity, and electrical conductivity. Like water, it is an excellent and often-used ionising solvent.Greenwood and Earnshaw, pp. 420–4 Over twenty other hydrides of nitrogen are known, the most important being hydrazine (N₂H₄) and hydrogen azide (HN₃). Hydrazine has physical properties that are remarkably similar to those of water: its melting and boiling points are 2.0 °C and 113.5 °C, the density of the solid at −5 °C is 1.146 g/cm³, while that of the liquid at 25 °C is 1.00 g/cm³.Greenwood and Earnshaw, pp. 426–7 The azanes are a series which include ammonia, hydrazine and triazane.

Phosphine, a toxic, colourless gas, is the most stable phosphorus hydride. It is insoluble in water but soluble in organic liquids (as well as carbon disulfide and trichloroacetic acid). Phosphine is a reducing agent.

Arsine, stibine, and bismuthine are highly toxic, thermally unstable, and colourless gases. No appreciable hydrogen bonding is found in phosphine, arsine, stibine or bismuthine, and there is no appreciable tendency to dissociate like ammonia to {{chem|MH|4|+}} and {{chem|MH|2|-}} (M = P, As, Sb, Bi). The pnictogen hydrides become denser down the group and the M–H bond lengths increase, while the H–M–H bond angle decreases slightly. The standard enthalpies of formation reflect the increasing thermal instability going down the group. Arsine decomposes to arsenic and hydrogen at 250–300 °C, stibine to antimony and hydrogen at room temperature, and bismuthine to bismuth and hydrogen above −45 °C. Arsine and stibine are very easily oxidised to arsenic or antimony trioxide and water; a similar reaction happens with sulfur or selenium. Reaction with metals at elevated temperatures leads to arsenides and antimonides. A few lower hydrides are known, such as As₂H₄, but they are even more unstable and their properties are unknown.Greenwood and Earnshaw, pp. 557–8

Imidogen, a radical composed of one hydrogen atom and one nitrogen atom (NH), can be classed as a pnictogen hydride.

References

Bibliography

{{Greenwood&Earnshaw2nd}}

Category:Hydrogen compounds

Category:Hydrides

Category:Pnictogens