hydrogen chalcogenide

{{multiple image|align=right|direction=vertical|width=105|image1=Water-3D-balls.png|image2=Hydrogen-sulfide-3D-balls.png|image3=Hydrogen-selenide-3D-balls.png|caption3=Water, hydrogen sulfide, and hydrogen selenide, three simple hydrogen chalcogenides}}Hydrogen chalcogenides (also chalcogen hydrides or hydrogen chalcides) are binary compounds of hydrogen with chalcogen atoms (elements of group 16: oxygen, sulfur, selenium, tellurium, polonium, and livermorium). Water, the first chemical compound in this series, contains one oxygen atom and two hydrogen atoms, and is the most common compound on the Earth's surface.{{cite web|url=https://www.cia.gov/the-world-factbook/countries/world/|title=CIA – The world factbook|publisher=Central Intelligence Agency|access-date=18 August 2016}}

Dihydrogen chalcogenides

The most important series, including water, has the chemical formula H₂X, with X representing any chalcogen. They are therefore triatomic. They take on a bent structure and as such are polar molecules. Water is an essential compound to life on Earth today,{{Cite web | url=https://www.un.org/waterforlifedecade/background.shtml | title=About the International Decade for Action 'Water for Life' 2005-2015}} covering 70.9% of the planet's surface. The other hydrogen chalcogenides are usually extremely toxic, and have strong unpleasant scents usually resembling rotting eggs or vegetables. Hydrogen sulfide is a common product of decomposition in oxygen-poor environments and as such is one chemical responsible for the smell of flatulence. It is also a volcanic gas. Despite its toxicity, the human body intentionally produces it in small quantities for use as a signaling molecule.

Water can dissolve the other hydrogen chalcogenides (at least those up to hydrogen telluride), forming acidic solutions known as hydrochalcogenic acids. Although these are weaker acids than the hydrohalic acids, they follow a similar trend of acid strength increasing with heavier chalcogens, and also form in a similar way (turning the water into a hydronium ion H₃O⁺ and the solute into a XH⁻ ion). It is unknown if polonium hydride forms an acidic solution in water like its lighter homologues, or if it behaves more like a metal hydride (see also hydrogen astatide).

class="wikitable" style="margin: 1em auto 1em auto" ! Compound !! As aqueous solution !! Chemical formula !! Geometry !! pK_a !! model
style="text-align: center;" \| hydrogen oxide oxygen hydride water (oxidane)	water	{{chem2\|H2O}}	90px	13.995	100px
style="text-align: center;" \| hydrogen sulfide sulfur hydride (sulfane)	hydrosulfuric acid	{{chem2\|H2S}}	90px	7.0	100px
style="text-align: center;" \| hydrogen selenide selenium hydride (selane)	hydroselenic acid	{{chem2\|H2Se}}	90px	3.89	100px
style="text-align: center;" \| hydrogen telluride tellurium hydride (tellane)	hydrotelluric acid	{{chem2\|H2Te}}	90px	2.6	100px
style="text-align: center;" \| hydrogen polonide polonium hydride (polane)	hydropolonic acid	{{chem2\|H2Po}}	90px	?	100px
style="text-align: center;" \| hydrogen livermoride livermorium hydride (livermorane)	hydrolivermoric acid	{{chem2\|H2Lv}}		?	File:Livermorium-hydride-3D-balls.png

Some properties of the hydrogen chalcogenides follow:Greenwood and Earnshaw, pp. 766–7

class="wikitable" style="margin: 1em auto 1em auto" ! Property !! {{chem2\|H2O}} !! {{chem2\|H2S}} !! {{chem2\|H2Se}} !! {{chem2\|H2Te}} !! {{chem2\|H2Po}}
Melting point (°C) \| 0.0 \|\| −85.6 \|\| −65.7 \|\| −51 \|\| −35.3
Boiling point (°C) \| 100.0 \|\| −60.3 \|\| −41.3 \|\| −4 \|\| 36.1
$\Delta H^\circ_f \left(\mathrm{kJ \cdot mol}^{-1}\right)$ \| −285.9 \|\| +20.1 \|\| +73.0 \|\| +99.6 \|\| ?
Bond angle (H–X–H) (gas) \| 104.45° \|\| 92.1° \|\| 91° \|\| 90° \|\| 90.9° (predicted){{cite journal \|journal= Journal of Chemical Physics \|year= 1990 \|volume= 92 \|issue= 11 \|pages= 6604–6619 \|title= Electronic states and potential energy surfaces of H₂Te, H₂Po, and their positive ions \|last1= Sumathi \|first1= K. \|last2= Balasubramanian \|first2= K. \|doi=10.1063/1.458298\|bibcode= 1990JChPh..92.6604S }}
Dissociation constant (HX⁻, K₁) \| 1.8 × 10⁻¹⁶ \| 1.3 × 10⁻⁷ \| 1.3 × 10⁻⁴ \| 2.3 × 10⁻³ \| ?
Dissociation constant (X²⁻, K₂) \| 0 \| 7.1 × 10⁻¹⁵ \| 1 × 10⁻¹¹ \| 1.6 × 10⁻¹¹ \| ?

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

! Property !! {{chem2|H2O}} !! {{chem2|H2S}} !! {{chem2|H2Se}} !! {{chem2|H2Te}} !! {{chem2|H2Po}}

Melting point (°C)

| 0.0 || −85.6 || −65.7 || −51 || −35.3

Boiling point (°C)

| 100.0 || −60.3 || −41.3 || −4 || 36.1

\Delta H^\circ_f \left(\mathrm{kJ \cdot mol}^{-1}\right)

| −285.9 || +20.1 || +73.0 || +99.6 || ?

Bond angle (H–X–H) (gas)

| 104.45° || 92.1° || 91° || 90° || 90.9° (predicted){{cite journal |journal= Journal of Chemical Physics |year= 1990 |volume= 92 |issue= 11 |pages= 6604–6619 |title= Electronic states and potential energy surfaces of H₂Te, H₂Po, and their positive ions |last1= Sumathi |first1= K. |last2= Balasubramanian |first2= K. |doi=10.1063/1.458298|bibcode= 1990JChPh..92.6604S }}

Dissociation constant (HX⁻, K₁)

| 1.8 × 10⁻¹⁶

| 1.3 × 10⁻⁷

| 1.3 × 10⁻⁴

| 2.3 × 10⁻³

| ?

Dissociation constant (X²⁻, K₂)

| 0

| 7.1 × 10⁻¹⁵

| 1 × 10⁻¹¹

| 1.6 × 10⁻¹¹

| ?

File:Boiling-points_Chalcogen-Halogen.svgs; it can be seen that hydrogen fluoride similarly exhibits anomalous effects due to hydrogen bonding. Ammonia also misbehaves similarly.]]

File:Mp and bp of H2E (E=O,S,Se,Te,Po) Celsius vs atomic number.svg

Many of the anomalous properties of water compared to the rest of the hydrogen chalcogenides may be attributed to significant hydrogen bonding between hydrogen and oxygen atoms. Some of these properties are the high melting and boiling points (it is a liquid at room temperature), as well as the high dielectric constant and observable ionic dissociation. Hydrogen bonding in water also results in large values of heat and entropy of vaporisation, surface tension, and viscosity.Greenwood and Earnshaw, p. 623

The other hydrogen chalcogenides are highly toxic, malodorous gases. Hydrogen sulfide occurs commonly in nature and its properties compared with water reveal a lack of any significant hydrogen bonding.Greenwood and Earnshaw, p. 682 Since they are both gases at STP, hydrogen can be simply burned in the presence of oxygen to form water in a highly exothermic reaction; such a test can be used in beginner chemistry to test for the gases produced by a reaction as hydrogen will burn with a pop. Water, hydrogen sulfide, and hydrogen selenide may be made by heating their constituent elements together above 350 °C, but hydrogen telluride and polonium hydride are not attainable by this method due to their thermal instability; hydrogen telluride decomposes in moisture, in light, and in temperatures above 0 °C. Polonium hydride is unstable, and due to the intense radioactivity of polonium (resulting in self-radiolysis upon formation), only trace quantities may be obtained by treating dilute hydrochloric acid with polonium-plated magnesium foil. Its properties are somewhat distinct from the rest of the hydrogen chalcogenides, since polonium is a metal while the other chalcogens are not, and hence this compound is intermediate between a normal hydrogen chalcogenide or hydrogen halide such as hydrogen chloride, and a metal hydride like stannane. Like water, the first of the group, polonium hydride is also a liquid at room temperature. Unlike water, however, the strong intermolecular attractions that cause the higher boiling point are van der Waals interactions, an effect of the large electron clouds of polonium.

Dihydrogen dichalcogenides

Dihydrogen dichalcogenides have the chemical formula H₂X₂, and are generally less stable than the monochalcogenides, commonly decomposing into the monochalcogenide and the chalcogen involved.

The most important of these is hydrogen peroxide, H₂O₂, a pale blue, nearly colourless liquid that has a lower volatility than water and a higher density and viscosity. It is important chemically as it can be either oxidised or reduced in solutions of any pH, can readily form peroxometal complexes and peroxoacid complexes, as well as undergoing many proton acid/base reactions. In its less concentrated form hydrogen peroxide has some major household uses, such as a disinfectant or for bleaching hair; much more concentrated solutions are much more dangerous.

class="wikitable" style="margin: 1em auto 1em auto" ! Compound	Chemical formula	Bond length	Model
style="text-align:center;"\| hydrogen peroxide (dioxidane)	style="text-align:center;"\| H₂O₂	File:Wasserstoffperoxid.svg	File:Hydrogen-peroxide-3D-vdW.png
style="text-align:center;"\| hydrogen disulfide (disulfane)	style="text-align:center;"\| H₂S₂	File:Hydrogen disulfide bonds.png	File:Hydrogen-disulfide-3D-vdW.png
style="text-align:center;"\| hydrogen diselenide{{cite journal \|title= Oxidation of Aqueous Polyselenide Solutions. A Mechanistic Pulse Radiolysis Study \|first1= Andreas \|last1= Goldbach \|first2= Marie-Louise \|last2= Saboungi \|author-link2=Marie-Louise Saboungi \|first3= J. A. \|last3= Johnson \|first4= Andrew R. \|last4= Cook \|first5= Dan \|last5= Meisel \|journal= J. Phys. Chem. A \|year= 2000 \|volume= 104 \|issue= 17 \|pages= 4011–4016 \|doi= 10.1021/jp994361g \|bibcode= 2000JPCA..104.4011G }} (diselane)	style="text-align:center;"\| H₂Se₂	style="text-align:center;"\| —	File:Hydrogen-diselenide-3D-vdW.png
style="text-align:center;"\| hydrogen ditelluride{{cite journal \|last1=Hop \|first1=Cornelis E. C. A. \|last2=Medina \|first2=Marco A. \|date=1994 \|title=H₂Te₂ Is Stable in the Gas Phase \|journal=Journal of the American Chemical Society \|volume=1994 \|issue=116 \|pages=3163–4 \|doi=10.1021/ja00086a072}} (ditellane)	style="text-align:center;"\| H₂Te₂	style="text-align:center;"\| —	File:Hydrogen-ditelluride-3D-vdW.png

Some properties of the hydrogen dichalcogenides follow:

class="wikitable" style="margin: 1em auto 1em auto" ! Property ! H₂O₂ ! H₂S₂ ! H₂Se₂ ! H₂Te₂
Melting point (°C) \| −0.43 \| −89.6 \| ? \| ?
Boiling point (°C) \| 150.2 _(decomposes) \| 70.7 \| ? \| ?

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

! Property

! H₂O₂

! H₂S₂

! H₂Se₂

! H₂Te₂

Melting point (°C)

| −0.43

| −89.6

| ?

Boiling point (°C)

| 150.2 _(decomposes)

| 70.7

| ?

An alternative structural isomer of the dichalcogenides, in which both hydrogen atoms are bonded to the same chalcogen atom, which is also bonded to the other chalcogen atom, have been examined computationally. These H₂X⁺–X^– structures are ylides. This isomeric form of hydrogen peroxide, oxywater, has not been synthesized experimentally. The analogous isomer of hydrogen disulfide, thiosulfoxide, has been detected by mass spectrometry experiments.{{cite journal |title= Thiosulfoxides (X₂S=S) and disulfanes (XSSX): first observation of organic thiosulfoxides |first1= Pascal |last1= Gerbaux |first2= Jean-Yves |last2= Salpin |first3= Guy |last3= Bouchoux |first4= Robert |last4= Flammang |journal= International Journal of Mass Spectrometry |volume= 195/196 |year= 2000 |pages= 239–249 |doi= 10.1016/S1387-3806(99)00227-4 |bibcode= 2000IJMSp.195..239G }}

It is possible for two different chalcogen atoms to share a dichalcogenide, as in hydrogen thioperoxide (H₂SO); more well-known compounds of similar description include sulfuric acid (H₂SO₄).

Higher dihydrogen chalcogenides

All straight-chain hydrogen chalcogenides follow the formula {{chem2|H2X_{n}|}}.

Higher hydrogen polyoxides than {{chem2|H2O2}} are not stable.Greenwood and Earnshaw, pp. 633–8 Trioxidane, with three oxygen atoms, is a transient unstable intermediate in several reactions. The next two in the oxygen series, tetraoxidane and pentaoxidane, have also been synthesized and found to be highly reactive. An alternative structural isomer of trioxidane, in which the two hydrogen atoms are attached to the central oxygen of the three-oxygen chain rather than one on each end, has been examined computationally.

Beyond {{chem2|H2S}} and {{chem2|H2S2}}, many higher polysulfanes {{chem2|H2S_{n}|}} (n = 3–8) are known as stable compounds.R. Steudel "Inorganic Polysulfanes H₂S₂ with n > 1" in Elemental Sulfur and Sulfur-Rich Compounds II (Topics in Current Chemistry) 2003, Volume 231, pp 99-125. {{doi|10.1007/b13182}} They feature unbranched sulfur chains, reflecting sulfur's tendency for catenation. Starting with {{chem2|H2S2}}, all known polysulfanes are liquids at room temperature. {{chem2|H2S2}} is colourless while the other polysulfanes are yellow; the colour becomes richer as n increases, as do the density, viscosity, and boiling point. A table of physical properties is given below.Greenwood and Earnshaw, p. 683

class="wikitable" style="margin: 1em auto 1em auto" ! Compound ! Density at 20 °C (g·cm⁻³) ! Vapour pressure (mmHg) ! Extrapolated boiling point (°C)
{{chem2\|H2S}} \| 1.363 (g·dm⁻³) \| 1740 (kPa, 21 °C) \| −60
{{chem2\|H2S2}} \| 1.334 \| 87.7 \| 70
{{chem2\|H2S3}} \| 1.491 \| 1.4 \| 170
{{chem2\|H2S4}} \| 1.582 \| 0.035 \| 240
{{chem2\|H2S5}} \| 1.644 \| 0.0012 \| 285
{{chem2\|H2S6}} \| 1.688 \|? \|?
{{chem2\|H2S7}} \| 1.721 \|? \|?
{{chem2\|H2S8}} \| 1.747 \|? \|?

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

! Compound

! Density at 20 °C (g·cm⁻³)

! Vapour pressure (mmHg)

! Extrapolated boiling point (°C)

| 1.363 (g·dm⁻³)

| 1740 (kPa, 21 °C)

| −60

| 1.334

| 87.7

| 70

| 1.491

| 1.4

| 170

| 1.582

| 0.035

| 240

| 1.644

| 0.0012

| 285

| 1.688

| 1.721

| 1.747

However, they can easily be oxidised and are all thermally unstable, disproportionating readily to sulfur and hydrogen sulfide, a reaction for which alkali acts as a catalyst:

:{{chem2|8 H2S_{n} → 8 H2S + (n \s 1) S8}}

They also react with sulfite and cyanide to produce thiosulfate and thiocyanate respectively.

An alternative structural isomer of the trisulfide, in which the two hydrogen atoms are attached to the central sulfur of the three-sulfur chain rather than one on each end, has been examined computationally.{{cite journal |title= Chemical Bonding in Hypervalent Molecules Revised. 2. Application of the Atoms in Molecules Theory to Y₂XZ and Y₂XZ₂ (Y = H, F, CH₃; X = O, S, Se; Z = O, S) Compounds |first1= J. A. |last1= Dobado |first2= Henar |last2= Martínez-García |first3= José |last3= Molina |first4= Markku R. |last4= Sundberg |journal= J. Am. Chem. Soc. |year= 1999 |volume= 121 |issue= 13 |pages = 3156–3164 |doi= 10.1021/ja9828206 }} Thiosulfurous acid, a branched isomer of the tetrasulfide, in which the fourth sulfur is bonded to the central sulfur of a linear dihydrogen trisulfide structure ({{chem2|(HS)2S+\sS–}}), has also been examined computationally.{{cite journal |title= Ab initio study of hypervalent sulfur hydrides as model intermediates in the interconversion reactions of compounds containing sulfur–sulfur bonds |first1= Risto S. |last1= Laitinen |first2= Tapani A. |last2= Pakkanen |first3= Ralf |last3= Steudel |journal= J. Am. Chem. Soc. |year= 1987 |volume= 109 |issue= 3 |pages= 710–714 |doi= 10.1021/ja00237a012 }} Thiosulfuric acid, in which two sulfur atoms branch off of the central of a linear dihydrogen trisulfide structure has been studied computationally as well.{{cite journal |title= Hypervalency in sulfur? Ab initio and DFT studies of the structures of thiosulfate and related sulfur oxyanions |last1= Nishimoto |first1= Akiko |last2= Zhang |first2= Daisy Y. |journal= Sulfur Letters |issue= 5/6 |year= 2003 |volume= 26 |pages= 171–180 |doi= 10.1080/02786110310001622767 |s2cid= 95470892 }}

Higher polonium hydrides may exist.{{Cite arXiv |eprint = 1503.08587|last1 = Liu|first1 = Yunxian|title = Phase diagram and superconductivity of polonium hydrides under high pressure|last2 = Duan|first2 = Defang|last3 = Tian|first3 = Fubo|last4 = Li|first4 = Da|last5 = Sha|first5 = Xiaojing|last6 = Zhao|first6 = Zhonglong|last7 = Zhang|first7 = Huadi|last8 = Wu|first8 = Gang|last9 = Yu|first9 = Hongyu|last10 = Liu|first10 = Bingbing|last11 = Cui|first11 = Tian|class = cond-mat.supr-con|year = 2015}}

Other hydrogen-chalcogen compounds

File:Heavy-water-3D-vdW.svg

Some monohydrogen chalcogenide compounds do exist and others have been studied theoretically. As radical compounds, they are quite unstable. The two simplest are hydroxyl (HO) and hydroperoxyl (HO₂). The compound hydrogen ozonide (HO₃) is also known,{{cite journal |first1= F. |last1= Cacace |first2= G. |last2= de Petris |first3= F. |last3= Pepi |first4= A. |last4= Troiani |title= Experimental Detection of Hydrogen Trioxide |journal= Science |volume= 285 |issue= 5424 |year= 1999 |pages= 81–82 |doi= 10.1126/science.285.5424.81 |pmid= 10390365 }} along with some of its alkali metal ozonide salts are (various MO₃).Wiberg 2001, p. 497 The respective sulfur analogue for hydroxyl is sulfanyl (HS) and HS₂ for hydroperoxyl.

{{multiple image|align=right|direction=vertical|width=105|image1=Hydroxide-3D-balls.png|caption1=HO⁻|image2=Water-3D-balls.png|caption2=H₂O|image3=Hydronium-3D-balls.png|caption3=H₃O⁺}}

One or both of the protium atoms in water can be substituted with the isotope deuterium, yielding respectively semiheavy water and heavy water, the latter being one of the most famous deuterium compounds. Due to the high difference in density between deuterium and regular protium, heavy water exhibits many anomalous properties. The radioisotope tritium can also form tritiated water in much the same way. Another notable deuterium chalcogenide is deuterium disulfide. Deuterium telluride (D₂Te) has slightly higher thermal stability than protium telluride, and has been used experimentally for chemical deposition methods of telluride-based thin films.Xiao, M. & Gaffney, T. R. Tellurium (Te) Precursors for Making Phase Change Memory Materials. (Google Patents, 2013) (https://www.google.ch/patents/US20130129603)

Hydrogen shares many properties with the halogens; substituting the hydrogen with halogens can result in chalcogen halide compounds such as oxygen difluoride and dichlorine monoxide, alongside ones that may be impossible with hydrogen such as chlorine dioxide.

=Hydrogen Ions=

One of the most well-known hydrogen chalcogenide ions is the hydroxide ion, and the related hydroxy functional group. The former is present in alkali metal, alkaline earth, and rare-earth hydroxides, formed by reacting the respective metal with water. The hydroxy group appears commonly in organic chemistry, such as within alcohols. The related bisulfide/sulfhydryl group appears in hydrosulfide salts and thiols, respectively.

The hydronium (H₃O⁺) ion is present in aqueous acidic solutions, including the hydrochalcogenic acids themselves, as well as pure water alongside hydroxide.

References

Bibliography

{{Greenwood&Earnshaw2nd}}

Category:Chalcogenides

Category:Hydrogen compounds