Oxidation states [a] | |
---|---|
−3 | [Ir(CO) 33− |
−1 | [Ir(CO)3(PPh3)]1− |
0 | Ir4(CO)12 |
+1 | [IrCl(CO)(PPh3)2 |
+2 | Ir(C5H5)2 |
+3 | IrCl3 |
+4 | IrO2 |
+5 | Ir4F20 |
+6 | IrF 6 |
+7 | [Ir(O2)O2+ |
+8 | IrO4 |
+9 | [IrO4+ [1] |
Iridium compounds are compounds containing the element iridium (Ir). Iridium forms compounds in oxidation states between −3 and +9, but the most common oxidation states are +1, +2, +3, and +4. [2] Well-characterized compounds containing iridium in the +6 oxidation state include IrF6 and the oxides Sr2MgIrO6 and Sr2CaIrO6. [2] [3] iridium(VIII) oxide (IrO4) was generated under matrix isolation conditions at 6 K in argon. [4] The highest oxidation state (+9), which is also the highest recorded for any element, is found in gaseous [IrO4+. [1]
Only one
binary oxide is well-characterized:
Iridium dioxide, IrO
2. It is a blue-black solid. The compound adopts the TiO2
rutile structure, featuring six coordinate iridium and three coordinate oxygen.
[5] It adopts the
fluorite structure.
[2] A
sesquioxide, Ir
2O
3, has been described as a blue-black powder, which is oxidized to IrO
2 by HNO
3.
[6] The corresponding disulfides, diselenides, sesquisulfides, and sesquiselenides are known, as well as IrS
3.
[2]
Another oxide,
iridium tetroxide, is also known, with iridium in the +8 oxiation state.
[7] This compound was formed by photochemical rearrangement of [(
η1-O2)IrO2] in solid
argon at a temperature of 6 K (−267.15 °C; −448.87 °F). At higher temperatures, the oxide is unstable.
[8] The detection of the iridium tetroxide cation IrO+
4 by
infrared photodissociation spectroscopy with formal oxidation state +9 has been reported, the highest currently known of any element, though the +10 oxidation state has been theorized for
platinum, but not confirmed.
[9]
[10]
Binary trihalides, IrX
3 are known for all of the halogens.
[2] For oxidation states +4 and above, only the
tetrafluoride,
pentafluoride and
hexafluoride are known.
[2] Iridium hexafluoride, IrF
6, is a volatile yellow solid, composed of octahedral molecules. It decomposes in water and is reduced to
IrF
4,.
[2] Iridium pentafluoride is also a strong oxidant, but it is a
tetramer, Ir
4F
20, formed by four corner-sharing octahedra.
[2]
The coordination complexes of iridium are extensive.
Iridium in its complexes is always
low-spin. Ir(III) and Ir(IV) generally form
octahedral complexes.
[2] Polyhydride complexes are known for the +5 and +3 oxidation states.
[11] One example is IrH5(PiPr3)2.
[12] The ternary hydride Mg
6Ir
2H
11 is believed to contain both the IrH4−
5 and the 18-electron IrH5−
4 anion.
[13]
Iridium also
oxyanions with oxidation states +4 and +5. K
2IrO
3 and KIrO
3 can be prepared from the reaction of
potassium oxide or
potassium superoxide with iridium at high temperatures. Such solids are not soluble in conventional solvents.
[14]
As for many elements, the chlorides are key complexes. Hexachloroiridic(IV) acid, H
2IrCl
6, and its ammonium salt are the most common iridium compounds from an industrial and preparative perspectives.
[15] They are intermediates in the purification of iridium and used as precursors for most other iridium compounds, as well as in the preparation of
anode coatings. The IrCl2−
6 ion has an intense dark brown color, and can be readily reduced to the lighter-colored IrCl3−
6 and vice versa.
[15]
Iridium trichloride, IrCl
3, which can be obtained in anhydrous form from direct oxidation of iridium powder by
chlorine at 650 °C,
[15] or in hydrated form by dissolving Ir
2O
3 in
hydrochloric acid, is often used as a starting material for the synthesis of other Ir(III) compounds.
[2] Another compound used as a starting material is ammonium hexachloroiridate(III), (NH
4)
3IrCl
6.
In the presence of air, iridium metal dissolves in molten alkali-metal cyanides to produce the Ir(CN)3−
6 (hexacyanoiridate) ion.
Iridium forms oxyanions in the +4 oxidation state. It forms compounds such as lithium iridate (Li2IrO3), which forms black crystals with three slightly different layered atomic structures, α, β, and sometimes γ. Lithium iridate exhibits metal-like, temperature-independent electrical conductivity, [17] and changes its magnetic ordering from paramagnetic to antiferromagnetic upon cooling to 15 K. [16] Lithium iridate is a potential electrode material for the lithium-ion battery. [17] This application is hindered by the high costs of Ir, as compared to the cheaper Li2MnO3 alternative. [18]
Organoiridium compounds contain iridium–
carbon bonds. Early studies identified the very stable
tetrairidium dodecacarbonyl, Ir
4(CO)
12.
[2] In this compound, each of the iridium atoms is bonded to the other three, forming a tetrahedral cluster. The discovery of
Vaska's complex (IrCl(CO)[P(C
6H
5)
3
2) opened the door for
oxidative addition reactions, a process fundamental to useful reactions. For example,
Crabtree's catalyst, a
homogeneous catalyst for
hydrogenation reactions.
[19]
[20] Iridium is usually supplied commercially in the Ir(III) and Ir(IV) oxidation states. Important starting reagents being hydrated
iridium trichloride and
ammonium hexachloroiridate. These salts are reduced upon treatment with CO, hydrogen, and alkenes. Illustrative is the carbonylation of the trichloride:
Many organoiridium(III) compounds are generated from pentamethylcyclopentadienyl iridium dichloride dimer. Many of derivatives feature kinetically inert cyclometalated ligands. [23] Related half-sandwich complexes were central in the development of C-H activation. [24] [25]
Iridium complexes played a pivotal role in the development of carbon–hydrogen bond activation (C–H activation), which promises to allow functionalization of hydrocarbons, which are traditionally regarded as unreactive. [26]
Oxidation states [a] | |
---|---|
−3 | [Ir(CO) 33− |
−1 | [Ir(CO)3(PPh3)]1− |
0 | Ir4(CO)12 |
+1 | [IrCl(CO)(PPh3)2 |
+2 | Ir(C5H5)2 |
+3 | IrCl3 |
+4 | IrO2 |
+5 | Ir4F20 |
+6 | IrF 6 |
+7 | [Ir(O2)O2+ |
+8 | IrO4 |
+9 | [IrO4+ [1] |
Iridium compounds are compounds containing the element iridium (Ir). Iridium forms compounds in oxidation states between −3 and +9, but the most common oxidation states are +1, +2, +3, and +4. [2] Well-characterized compounds containing iridium in the +6 oxidation state include IrF6 and the oxides Sr2MgIrO6 and Sr2CaIrO6. [2] [3] iridium(VIII) oxide (IrO4) was generated under matrix isolation conditions at 6 K in argon. [4] The highest oxidation state (+9), which is also the highest recorded for any element, is found in gaseous [IrO4+. [1]
Only one
binary oxide is well-characterized:
Iridium dioxide, IrO
2. It is a blue-black solid. The compound adopts the TiO2
rutile structure, featuring six coordinate iridium and three coordinate oxygen.
[5] It adopts the
fluorite structure.
[2] A
sesquioxide, Ir
2O
3, has been described as a blue-black powder, which is oxidized to IrO
2 by HNO
3.
[6] The corresponding disulfides, diselenides, sesquisulfides, and sesquiselenides are known, as well as IrS
3.
[2]
Another oxide,
iridium tetroxide, is also known, with iridium in the +8 oxiation state.
[7] This compound was formed by photochemical rearrangement of [(
η1-O2)IrO2] in solid
argon at a temperature of 6 K (−267.15 °C; −448.87 °F). At higher temperatures, the oxide is unstable.
[8] The detection of the iridium tetroxide cation IrO+
4 by
infrared photodissociation spectroscopy with formal oxidation state +9 has been reported, the highest currently known of any element, though the +10 oxidation state has been theorized for
platinum, but not confirmed.
[9]
[10]
Binary trihalides, IrX
3 are known for all of the halogens.
[2] For oxidation states +4 and above, only the
tetrafluoride,
pentafluoride and
hexafluoride are known.
[2] Iridium hexafluoride, IrF
6, is a volatile yellow solid, composed of octahedral molecules. It decomposes in water and is reduced to
IrF
4,.
[2] Iridium pentafluoride is also a strong oxidant, but it is a
tetramer, Ir
4F
20, formed by four corner-sharing octahedra.
[2]
The coordination complexes of iridium are extensive.
Iridium in its complexes is always
low-spin. Ir(III) and Ir(IV) generally form
octahedral complexes.
[2] Polyhydride complexes are known for the +5 and +3 oxidation states.
[11] One example is IrH5(PiPr3)2.
[12] The ternary hydride Mg
6Ir
2H
11 is believed to contain both the IrH4−
5 and the 18-electron IrH5−
4 anion.
[13]
Iridium also
oxyanions with oxidation states +4 and +5. K
2IrO
3 and KIrO
3 can be prepared from the reaction of
potassium oxide or
potassium superoxide with iridium at high temperatures. Such solids are not soluble in conventional solvents.
[14]
As for many elements, the chlorides are key complexes. Hexachloroiridic(IV) acid, H
2IrCl
6, and its ammonium salt are the most common iridium compounds from an industrial and preparative perspectives.
[15] They are intermediates in the purification of iridium and used as precursors for most other iridium compounds, as well as in the preparation of
anode coatings. The IrCl2−
6 ion has an intense dark brown color, and can be readily reduced to the lighter-colored IrCl3−
6 and vice versa.
[15]
Iridium trichloride, IrCl
3, which can be obtained in anhydrous form from direct oxidation of iridium powder by
chlorine at 650 °C,
[15] or in hydrated form by dissolving Ir
2O
3 in
hydrochloric acid, is often used as a starting material for the synthesis of other Ir(III) compounds.
[2] Another compound used as a starting material is ammonium hexachloroiridate(III), (NH
4)
3IrCl
6.
In the presence of air, iridium metal dissolves in molten alkali-metal cyanides to produce the Ir(CN)3−
6 (hexacyanoiridate) ion.
Iridium forms oxyanions in the +4 oxidation state. It forms compounds such as lithium iridate (Li2IrO3), which forms black crystals with three slightly different layered atomic structures, α, β, and sometimes γ. Lithium iridate exhibits metal-like, temperature-independent electrical conductivity, [17] and changes its magnetic ordering from paramagnetic to antiferromagnetic upon cooling to 15 K. [16] Lithium iridate is a potential electrode material for the lithium-ion battery. [17] This application is hindered by the high costs of Ir, as compared to the cheaper Li2MnO3 alternative. [18]
Organoiridium compounds contain iridium–
carbon bonds. Early studies identified the very stable
tetrairidium dodecacarbonyl, Ir
4(CO)
12.
[2] In this compound, each of the iridium atoms is bonded to the other three, forming a tetrahedral cluster. The discovery of
Vaska's complex (IrCl(CO)[P(C
6H
5)
3
2) opened the door for
oxidative addition reactions, a process fundamental to useful reactions. For example,
Crabtree's catalyst, a
homogeneous catalyst for
hydrogenation reactions.
[19]
[20] Iridium is usually supplied commercially in the Ir(III) and Ir(IV) oxidation states. Important starting reagents being hydrated
iridium trichloride and
ammonium hexachloroiridate. These salts are reduced upon treatment with CO, hydrogen, and alkenes. Illustrative is the carbonylation of the trichloride:
Many organoiridium(III) compounds are generated from pentamethylcyclopentadienyl iridium dichloride dimer. Many of derivatives feature kinetically inert cyclometalated ligands. [23] Related half-sandwich complexes were central in the development of C-H activation. [24] [25]
Iridium complexes played a pivotal role in the development of carbon–hydrogen bond activation (C–H activation), which promises to allow functionalization of hydrocarbons, which are traditionally regarded as unreactive. [26]