Indium halides

Class of chemical compounds

There are three sets of Indium halides, the trihalides, the monohalides, and several intermediate halides. In the monohalides the oxidation state of indium is +1 and their proper names are indium(I) fluoride, indium(I) chloride, indium(I) bromide and indium(I) iodide.

The intermediate halides contain indium with oxidation states, +1, +2 and +3.

Indium trihalides

In all of the trihalides the oxidation state of indium is +3, and their proper names are indium(III) fluoride, indium(III) chloride, indium(III) bromide, and indium(III) iodide. The trihalides are Lewis acidic. Indium trichloride is a starting point in the production of trimethylindium which is used in the semiconductor industry.

Indium(III) fluoride

InF₃ is a white solid, m.p. 1170 °C. Its structure contains 6 coordinate indium.

Indium(III) chloride

InCl₃ is a white solid, m.p. 586 °C. It is obtained by oxidation of indium with chlorine.^[1] It is isostructural with AlCl₃.

Indium(III) bromide

InBr₃ is a pale yellow solid, m.p. 435 °C. It is isostructural with AlCl₃. It is prepared by combining the elements.^[2] InBr₃ finds some use in organic synthesis as a water tolerant Lewis acid.^[3]

Indium(III) iodide

Ball-and-stick model of the In₂I₆ molecule

InI₃ is a yellow solid. It is obtained by evaporation of a solution of indium in HI.^[4] Distinct yellow and a red forms are known. The red form undergoes a transition to the yellow at 57 °C. The structure of the red form has not been determined by X-ray crystallography, however spectroscopic evidence indicates that indium may be six coordinate.^[5] The yellow form consists of In₂I₆ with 4 coordinate indium centres. It is used as an "iodide getter" in the Cativa process.^{[citation needed]}

Intermediate halides

A surprising number of intermediate chlorides and bromides are known, but only one iodide, and no difluoride. Rather than the apparent oxidation state of +2, these compounds contain indium in the +1 and +3 oxidation states. Thus the diiodide is described as In^IIn^IIIX₄. It was some time later that the existence of compounds containing the anion In₂Br2−6 were confirmed which contains an indium-indium bond. Early work on the chlorides and bromides involved investigations of the binary phase diagrams of the trihalides and the related monohalide. Many of the compounds were initially misidentified as many of them are incongruent and decompose before melting. The majority of the previously reported chlorides and bromides have now either had their existence and structures confirmed by X Ray diffraction studies or have been consigned to history. Perhaps the most unexpected case of mistaken identity was the surprising result that a careful reinvestigation of the InCl/InCl₃ binary phase diagram did not find InCl₂.^[6]
The reason for this abundance of compounds is that indium forms 4 and 6 coordinate anions containing indium(III) e.g. InBr−4, InCl3−6 as well as the anion In₂Br2−6 that surprisingly contains an indium-indium bond.

In₇Cl₉ and In₇Br₉

In₇Cl₉ is yellow solid stable up to 250 °C that is formulated In^I₆(In^IIICl₆)Cl₃^[7]

In₇Br₉ has a similar structure to In₇Cl₉ and can be formulated as In^I₆(In^IIIBr₆)Br₃^[8]

In₅Br₇

In₅Br₇ is a pale yellow solid. It is formulated In^I₃(In^II₂Br₆)Br. The In^II₂Br₆ anion has an eclipsed ethane like structure with a metal-metal bond length of 270 pm.^[9]

In₂Cl₃ and In₂Br₃

In₂Cl₃ is colourless and is formulated In^I₃ In^IIICl₆^[10] In contrast In₂Br₃ contains the In₂Br₆ anion as present in In₅Br₇, and is formulated In^I₂(In^II₂Br₆) with a structure similar to Ga₂Br₃.^[11]

In₄Br₇

In₄Br₇ is near colourless with a pale greenish yellow tint. It is light sensitive (like TlCl and TlBr) decaying to InBr₂ and In metal. It is a mixed salt containing the InBr−4 and InBr3−6 anions balanced by In⁺ cations. It is formulated In^I₅(In^IIIBr₄)₂(In^IIIBr₆) The reasons for the distorted lattice have been ascribed to an antibonding combination between doubly filled, non-directional indium 5s orbitals and neighboring bromine 4p hybrid orbitals.^[12]

In₅Cl₉

In₅Cl₉ is formulated as In^I₃In^III₂Cl₉. The In₂Cl3−9 anion has two 6 coordinate indium atoms with 3 bridging chlorine atoms, face sharing bioctahedra, with a similar structure to Cr₂Cl2−9 and Tl₂Cl2−9.^[13]

InBr₂

InBr₂ is a greenish white crystalline solid, which is formulated In^IIn^III Br₄. It has the same structure as GaCl₂. InBr₂ is soluble in aromatic solvents and some compounds containing η⁶-arene In(I) complexes have been identified. (See hapticity for an explanation of the bonding in such arene-metal ion complexes). With some ligands InBr₂ forms neutral complexes containing an indium-indium bond.^[14]

InI₂

InI₂ is a yellow solid that is formulated In^IIn^IIII₄.

Monohalides

The solid monohalides InCl, InBr and InI are all unstable with respect to water, decomposing to the metal and indium(III) species. They fall between gallium(I) compounds, which are more reactive and thallium(I) that are stable with respect to water. InI is the most stable. Up until relatively recently the monohalides have been scientific curiosities, however with the discovery that they can be used to prepare indium cluster and chain compounds they are now attracting much more interest.^[15]

InF

InF only known as an unstable gaseous compound.

InCl

The room temperature form of InCl is yellow, with a cubic distorted NaCl structure. The red high temperature (>390 K) form has the ${\ce {\beta-TlI}}$ structure.^[15]

InBr

InBr is a red crystalline solid, mp 285 °C. It has the same structure as ${\ce {\beta-TlI}}$ , with an orthorhombic distorted rock salt structure. It can be prepared from indium metal and InBr₃.

InI

InI is a deep red purple crystalline solid. It has the same structure as ${\ce {\beta-TlI}}$ . It can be made by direct combination of its constituent elements at high temperature. Alternatively it can be prepared from InI₃ and indium metal in refluxing xylenes.^[16] It is the most stable of the solid monohalides and is soluble in some organic solvents. Solutions of InI in a pyridine/m-xylene mixture are stable below 243 K.^[15]

Anionic halide complexes of In(III)

The trihalides are Lewis Acids and form addition compounds with ligands. For InF₃ there are few examples known however for the other halides addition compounds with tetrahedral, trigonal bipyramidal and octahedral coordination geometries are known. With halide ions there are examples of all of these geometries along with some anions with octahedrally coordinated indium and with bridging halogen atoms, In₂X3−9 with three bridging halogen atoms and In₂X−7 with just one. Additionally there are examples of indium with square planar geometry in the InX₅²⁻ ion. The square planar geometry of InCl2−5 was the first found for a main group element.

InX−4 and InX3−6

Salts of InCl−4, InBr−4 and InI−4 are known. The salt LiInF₄ has been prepared,^[17]^[18] however it has an unusual layer structure with octahedrally coordinated indium center. Salts of InF₆³⁻, InCl3−6 and InBr3−6 ^[19] have all been made.

InCl2−5 and InBr2−5

The InCl2−5 ion has been found to be square pyramidal in the salt (NEt4)₂InCl₅, with the same structure as (NEt₄)₂ TlCl₅, but is trigonal bipyramidal in tetraphenylphosphonium pentachloroindate acetonitrile solvate.^[20]

The InBr2−5 ion has similarly been found square pyramidal, albeit distorted, in the Bis(4-chloropyridinium) salt ^[21] and trigonal bipyramidal ^[22] in Bi₃₇InBr₄₈.

In₂X−7

The In₂X−7 ions contain a single bridging halogen atom. Whether the bridge is bent or linear cannot be determined from the spectra. The chloride and bromide have been detected using electrospray mass spectrometry. The In₂I−7 ion has been prepared in the salt CsIn₂I₇.^[5]

In₂X3−9

The caesium salts of In₂Cl3−9 and In₂Br3−9 both contain binuclear anions with octahedrally coordinated Indium atoms.^[13]

Anionic halide complexes of In(I) and In(II)

In^IX−2 and In^IX2−3

In^IX₂⁻ is produced when the In₂X₆²⁻ ion disproportionates. Salts containing the In^IX2−3 ions have been made and their vibrational spectra interpreted as showing that they have C_3v symmetry, trigonal pyramidal geometry, with structures similar to the isoelectronic SnX−3 ions.

In₂Cl2−6, In₂Br2−6 and In₂I2−6

Salts of the chloride, bromide and iodide ions (Bu₄N)₂In₂X₆ have been prepared. In non-aqueous solvents this ion disproportionates to give In^IX−2 and In^IIIX−4.

Neutral Indium(II) halide adducts

Following the discovery of the In₂Br₆²⁻ a number of related neutral compounds containing the In^II₂X₄ kernel have been formed from the reaction of indium dihalides with neutral ligands.^[14] Some chemists refer to these adducts, when used as the starting point for the synthesis of cluster compounds as ‘In₂X₄’ e.g. the TMEDA adduct.^[23]

General sources

WebElements Periodic Table » Indium » compounds information
Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Butterworth-Heinemann. ISBN 978-0-08-037941-8.
Cotton, F. Albert; Wilkinson, Geoffrey; Murillo, Carlos A.; Bochmann, Manfred (1999), Advanced Inorganic Chemistry (6th ed.), New York: Wiley-Interscience, ISBN 0-471-19957-5

References

^ E. Donges (1963). "Indium(III) chloride". In G. Brauer (ed.). Handbook of Preparative Inorganic Chemistry, 2nd Ed. Vol. 1. NY, NY: Academic Press. pp. 858–859.
^ E. Donges (1963). "Indium(III) bromide". In G. Brauer (ed.). Handbook of Preparative Inorganic Chemistry, 2nd Ed. Vol. 1. NY, NY: Academic Press. pp. 859–860.
^ Zhang, Zhan-Hui (2005). "Indium Tribromide: A Water-Tolerant Green Lewis Acid". Synlett (4). Georg Thieme Verlag KG: 711–712. doi:10.1055/s-2005-863726. ISSN 0936-5214.
^ E. Donges (1963). "Indium(III) Iodide". In G. Brauer (ed.). Handbook of Preparative Inorganic Chemistry, 2nd Ed. Vol. 1. NY, NY: Academic Press. pp. 861–2.
^ ^a ^b Taylor, Michael J.; Kloo, Lars A. (2000). "Raman investigations of indium iodide complexes: evidence for the In₂I₇⁻ ion". Journal of Raman Spectroscopy. 31 (6). Wiley: 465–468. doi:10.1002/1097-4555(200006)31:6<465::aid-jrs557>3.0.co;2-7. ISSN 0377-0486.
^ Meyer, Gerd; Blachnik, Roger (1983). "Neue Untersuchungen an gemischtvalenten Indium(I, III)- chloriden: Das Phasendiagramm In/Cl im Bereich 30-50 mol-% In und die Kristallstruktur von In₅Cl₉". Zeitschrift für anorganische und allgemeine Chemie (in German). 503 (8). Wiley: 126–132. doi:10.1002/zaac.19835030813. ISSN 0044-2313.
^ Beck, Horst Philipp; Wilhelm, Doris (1991). "In₇Cl₉—A New "Old" Compound in the System In-Cl". Angewandte Chemie International Edition in English. 30 (7). Wiley: 824–825. doi:10.1002/anie.199108241. ISSN 0570-0833.
^ Dronskowski, R., ed. (1995-12-01). "The crystal structure of In₇Br₉". Zeitschrift für Kristallographie - Crystalline Materials. 210 (12). Walter de Gruyter GmbH: 920–923. doi:10.1524/zkri.1995.210.12.920. ISSN 2194-4946.
^ Ruck, Michael; Bärnighausen, Hartmut (1999). "Zur Polymorphie von In₅Br₇". Zeitschrift für anorganische und allgemeine Chemie (in German). 625 (4). Wiley: 577–585. doi:10.1002/(sici)1521-3749(199904)625:4<577::aid-zaac577>3.0.co;2-b. ISSN 0044-2313.
^ Meyer, Gerd (1981). "Das Indiumsesquichlorid, In₂Cl₃: ein pseudobinäres, gemischtvalentes Indium(I)-hexachloroindat(III)". Zeitschrift für anorganische und allgemeine Chemie (in German). 478 (7). Wiley: 39–51. doi:10.1002/zaac.19814780705. ISSN 0044-2313.
^ Staffel, Thomas; Meyer, Gerd (1987). "The mono-, sesqui-, and dibromides of indium: InBr, In₂Br₃, and InBr₂". Zeitschrift für anorganische und allgemeine Chemie (in German). 552 (9). Wiley: 113–122. doi:10.1002/zaac.19875520913. ISSN 0044-2313.
^ Dronskowski, Richard (1995-06-02). "Synthesis, Structure, and Decay of In₄Br₇". Angewandte Chemie International Edition in English. 34 (10). Wiley: 1126–1128. doi:10.1002/anie.199511261. ISSN 0570-0833.
^ ^a ^b Meyer, Gerd (1978). "Zur Kenntnis der Chloro- und Bromo-Indate (III). A₃In₂Cl₉ (A = Cs, Rb, In, Tl) und Cs₃In₂Br_9−xCl_x (x = 0, 3, 6, 7, 8)". Zeitschrift für anorganische und allgemeine Chemie (in German). 445 (1). Wiley: 140–146. doi:10.1002/zaac.19784450117. ISSN 0044-2313.
^ ^a ^b Sinclair, Ian; Worrall, Ian J. (1982-03-15). "Neutral complexes of the indium dihalides". Canadian Journal of Chemistry. 60 (6). Canadian Science Publishing: 695–698. doi:10.1139/v82-102. ISSN 0008-4042.
^ ^a ^b ^c Pardoe, J. A.; Downs, A. J. (2007). "Development of the chemistry of indium in formal oxidation States lower than +3". Chemical Reviews. 107 (1): 2–45. doi:10.1021/cr068027+. PMID 17212469.
^ Organic Syntheses, Coll. Vol. 10, p.170 (2004); Vol. 79, p.59 (2002)
^ Gravereau, P.; Chaminade, J. P.; Gaewdang, T.; Grannec, J.; Pouchard, M.; Hagenmuller, P. (1992). "Structure of lithium tetrafluoroindate". Acta Crystallographica Section C Crystal Structure Communications. 48 (5): 769–771. doi:10.1107/S0108270191011915.
^ Gravereau, P.; Chaminade, J. P.; Gaewdang, T.; Grannec, J.; Pouchard, M.; Hagenmuller, P. (1992-05-15). "Structure of lithium tetrafluoroindate". Acta Crystallographica Section C Crystal Structure Communications. 48 (5). International Union of Crystallography (IUCr): 769–771. doi:10.1107/s0108270191011915. ISSN 0108-2701.
^ Spiro, Thomas G. (1965). "Raman Spectra of Crystalline Chlorothallates". Inorganic Chemistry. 4 (9). American Chemical Society (ACS): 1290–1293. doi:10.1021/ic50031a013. ISSN 0020-1669.
^ Bubenheim, W.; Frenzen, G.; Müller, U. (1995-06-15). "Die Chloroindate [PPh₄]₂[In₂Cl₆] und [PPh₄]₂[InCl₅].CH₃CN". Acta Crystallographica Section C Crystal Structure Communications. 51 (6). International Union of Crystallography (IUCr): 1120–1124. doi:10.1107/s0108270194011789. ISSN 0108-2701.
^ Ishihara, Hideta; Dou, Shi-qi; Gesing, Thorsten M; Paulus, Helmut; Fuess, Hartmut; Weiss, Alarich (1998). "Crystal structures of [(CH₃)₂NH₂]₃InBr₆ and [4-ClC₅H₄NH]₂InBr₅". Journal of Molecular Structure. 471 (1–3). Elsevier BV: 175–182. doi:10.1016/s0022-2860(98)00444-x. ISSN 0022-2860.
^ Dubenskyy, Vitaly; Ruck, Michael (2003). "Bi₃₇InBr₄₈: Eine polares Subhalogenid mit Bi₉⁵⁺-Polykationen, komplexen Bromobismutat(III)-Anionen [Bi₃Br₁₃]^4— und [Bi₇Br₃₀]^9— sowie Pentabromoindat(III)-Anionen [InBr₅]^2—". Zeitschrift für anorganische und allgemeine Chemie (in German). 629 (3). Wiley: 375–380. doi:10.1002/zaac.200390062. ISSN 0044-2313.
^ Li, Xiao-Wang; Robinson, Gregory H.; Pennington, William T. (1996). "Disproportionation of Low Valent Indium Bromide: Synthesis and Molecular Structure of Bis (2, 6-Dimesityl-Phenyl) Indium Bromide, (2, 6-Mes₂C₆H₃)₂InBr (Mes = 2, 4, 6-Me₃C₆H₂). When does Trigonal Planar Become T-Shaped?". Main Group Chemistry. 1 (3). IOS Press: 301–307. doi:10.1080/13583149612331338587. ISSN 1024-1221.

Salts and covalent derivatives of the chloride ion

HCl

LiCl

BeCl₂

B₄Cl₄
B₁₂Cl₁₂
BCl₃
B₂Cl₄
+BO₃

C₂Cl₂
C₂Cl₄
C₂Cl₆
CCl₄
+C
+CO₃

NCl₃
ClN₃
+N
+NO₃

Cl_xO_y
Cl₂O
Cl₂O₂
ClO
ClO₂
Cl₂O₄
Cl₂O₆
Cl₂O₇
ClO₄
+O

ClF
ClF₃
ClF₅

NaCl

MgCl₂

AlCl
AlCl₃

Si₅Cl₁₂
Si₂Cl₆
SiCl₄

P₂Cl₄
PCl₃
PCl₅
+P

S₂Cl₂
SCl₂
SCl₄
+SO₄

Cl₂

KCl

CaCl
CaCl₂

ScCl₃

TiCl₂
TiCl₃
TiCl₄

VCl₂
VCl₃
VCl₄
VCl₅

CrCl₂
CrCl₃
CrCl₄

MnCl₂
MnCl₃

FeCl₂
FeCl₃

CoCl₂
CoCl₃

NiCl₂

CuCl
CuCl₂

ZnCl₂

GaCl
GaCl₃

GeCl₂
GeCl₄

AsCl₃
AsCl₅
+As

Se₂Cl₂
SeCl₂
SeCl₄

BrCl

RbCl

SrCl₂

YCl₃

ZrCl₃
ZrCl₄

NbCl₃
NbCl₄
NbCl₅

MoCl₂
MoCl₃
MoCl₄
MoCl₅
MoCl₆

TcCl₃
TcCl₄

RuCl₂
RuCl₃
RuCl₄

RhCl₃

PdCl₂

AgCl

CdCl₂

InCl
InCl₂
InCl₃

SnCl₂
SnCl₄

SbCl₃
SbCl₅

Te₃Cl₂
TeCl₂
TeCl₄

ICl
ICl₃

XeCl
XeCl₂
XeCl₄

CsCl

BaCl₂

LuCl₃

HfCl₄

TaCl₃
TaCl₄
TaCl₅

WCl₂
WCl₃
WCl₄
WCl₅
WCl₆

ReCl₃
ReCl₄
ReCl₅
ReCl₆

OsCl₂
OsCl₃
OsCl₄
OsCl₅

IrCl₂
IrCl₃
IrCl₄

PtCl₂
PtCl₄

AuCl
(Au[AuCl₄])₂
AuCl₃

Hg₂Cl₂
HgCl₂

TlCl
TlCl₃

PbCl₂
PbCl₄

BiCl₃

PoCl₂
PoCl₄

AtCl

FrCl

RaCl₂

LrCl₃

RfCl₄

DbCl₅

SgO₂Cl₂

BhO₃Cl

LaCl₃

CeCl₃

PrCl₃

NdCl₂
NdCl₃

PmCl₃

SmCl₂
SmCl₃

EuCl₂
EuCl₃

GdCl₃

TbCl₃

DyCl₂
DyCl₃

HoCl₃

ErCl₃

TmCl₂
TmCl₃

YbCl₂
YbCl₃

AcCl₃

ThCl₃
ThCl₄

PaCl₄
PaCl₅

UCl₃
UCl₄
UCl₅
UCl₆

NpCl₃

PuCl₃

AmCl₂
AmCl₃

CmCl₃

BkCl₃

CfCl₃

EsCl₂
EsCl₃

FmCl₂

MdCl₂

NoCl₂