Bis(benzene)chromium

Bis(benzene)chromium is the organometallic compound with the formula Cr(η⁶-C₆H₆)₂. It is sometimes called dibenzenechromium. The compound played an important role in the development of sandwich compounds in organometallic chemistry and is the prototypical complex containing two arene ligands.

Bis(benzene)chromium

Bis(benzene)chromium Bis(benzene)chromium
Bis(benzene)chromium (sublimated, under nitrogen)
Names
IUPAC name Bis(η6-benzene)chromium
Other names di(benzene)chromium dibenzenechromium
Identifiers
CAS Number	1271-54-1 Y
3D model (JSmol)	Interactive image
ChemSpider	10157111
ECHA InfoCard	100.013.675
EC Number	215-042-7
PubChem CID	11984611
RTECS number	GB5850000
CompTox Dashboard (EPA)	DTXSID40155402
InChI InChI=1S/2C6H6.Cr/c2*1-2-4-6-5-3-1;/h2*1-6H;/q;-6; Key: IWCQVOVBDXJJDF-UHFFFAOYSA-N
SMILES c1ccccc1.[Cr].c1ccccc1
Properties
Chemical formula	Cr(C6H6)2
Molar mass	208.224 g·mol−1
Appearance	brown-black crystals
Melting point	284 to 285 °C (543 to 545 °F; 557 to 558 K)
Boiling point	Sublimes at 160 °C (320 °F; 433 K) in vacuum
Solubility in water	insoluble
Solubility in other solvents	slightly: benzene, THF
Structure
Coordination geometry	pseudooctahedral
Dipole moment	0 D
Hazards
Occupational safety and health (OHS/OSH):
Main hazards	flammable
GHS labelling:
Pictograms
Signal word	Warning
Hazard statements	H228
Precautionary statements	P210, P240, P241, P280, P378
Flash point	82 °C; 180 °F; 355 K
Related compounds
Related compounds	Metallocene f-Block metallocene Actinocene Uranocene Zirconocene Vanadocene Chromocene Ferrocene Plumbocene
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa). Y verify (what is YN ?) Infobox references

Historical background

In the late 1910s, Franz Hein started the investigation of "triphenylchromium" by reacting chromium trichloride with a Grignard reagent, phenyl magnesium bromide. Such a reaction gave a mixture of phenyl chromium, and Hein suggested that it contained a Cr(VI) species, "(C₆H₅)₅CrBr", generated via valence disproportionation.^[1][2]

5 C₆H₅MgBr + 4 CrCl₃ → (C₆H₅)₅CrBr + 2 MgBr₂ + 3 MgCl₂ + 3 CrCl₂

This event marked an advance in organochromium chemistry at the time. "(C₆H₅)₅CrBr" was described as having salt-like properties. However, the reported workup procedures for "(C₆H₅)₅CrBr" was challenging, and the yield was low.^[1][2] Zeiss and Tsutsui found that Hein's formulation of the chromium-containing products was flawed.^[1]

Preparation

Ernst Otto Fischer proposed the synthesis of a chromium(0) complex with two benzene ligands, which would have a sandwich structure similar to that of ferrocene. In 1954, Walter Hafner, one of Fischer's PhD student put the idea into practice using the "Reductive Friedel-Crafts reaction."^[3][4] Before their preparation of bis(benzene)chromium, it was known that heating chromium trichloride, aluminium trichloride, and aluminium powder in benzene under high pressures of carbon monoxide affords chromium hexacarbonyl. Under these conditions the aluminium trichloride abstracts chloride from the chromium, and the aluminium metal reduces Cr(III). Hafner repeated this procedure but omitted the CO, resulting in the formation of yellow [Cr(C₆H₆)₂]⁺:

6 C₆H₆ + 3 CrCl₃ + 2 Al + x AlCl₃ → 3 [(C₆H₆)₂Cr][AlCl₄]·(x−1)AlCl₃

Excess aluminium trichloride is needed to solubilize the product.^[5] The product [(C₆H₆)₂Cr]⁺ is not particularly air-sensitive. The cation is then reduced by sodium dithionite in aqueous sodium hydroxide. The resulting solid was bis(benzene)chromium:^[5][6]

2 [(C₆H₆)₂Cr]⁺ + S₂O2−4 + 4 OH⁻ → 2 (C₆H₆)₂Cr + 2 SO2−3 + 2 H₂O

The synthesis was intensely examined. Among the many results was the finding that the procedure was catalyzed by the presence of mesitylene. Heating [Cr(C₆H₆)₂]⁺ with aqueous base results in disproportionation.^[7]

Fischer and Seus soon prepared Hein's [Cr(C₆H₅−C₆H₅)₂]⁺ by an unambiguous route, thus confirming that Hein had unknowingly discovered sandwich complexes, a half-century ahead of the work on ferrocene.^[8][9] Illustrating the rapid pace of this research, the same issue of Chem. Ber. also describes the Mo(0) complex.^[10]

Using the technique of metal vapor synthesis, bis(benzene)chromium and many analogous compounds can be prepared by co-condensation of Cr vapor and arenes. In this way, the phosphabenzene complex [Cr(C₅H₅P)₂] can be prepared.^[11]

Properties and characterization

Bis(benzene)chromium is thermally stable under an inert gas atmosphere. It is diamagnetic. In 1956, Fischer and Weiss determined structure of bis(benzene)chromium by X-ray crystallography. It crystallizes with centrosymmetry in a cubic space group.^[12] The Cr-C distances are 214.1 and the C-C distances are 141.6 picometers.^[13] The C-C bonds are elongated from 139 pm for free benzene.

According to electrochemical studies, the half-wave potential (E_1/2) of the +1/0 couple is around -1.10 to -1.25 V versus Ferrocenium/Ferrocene at room temperature.^[14][15][16]

Bonding and electronic structure

Theoretical chemical bonding of bis(benzene)chromium have been investigated since the discovery of this compound. The ground state configuration is (3e_2g)⁴(4a_1g)² (3e_2u)⁰. Analysis of the frontier orbitals suggested that the chromium-benzene interaction is largely contributed by the 𝝅 and/or 𝞭 interactions between the 3d metal orbitals and ligand 𝝅 orbitals.^[17][18] 3e_2g (HOMO-1) and 3e_1g (HOMO-2) molecular orbitals are 𝞭-bonding interactions between metal 3d𝞭 and ligand 𝝅 orbitals. The highest occupied molecular orbital (HOMO), 4a_1g, is the non-bonding metal d_z2 orbital. The lowest unoccupied molecular orbital (LUMO) is 3e_2u, which is purely ligand 𝝅 orbital. As for 4e_1g (LUMO+1) and 4e_2g (LUMO+2), they are composed of anti-bonding interaction between 3d𝝅 and ligand 𝝅 orbitals.

Molecular orbitals of bis(benzene)chromium, visualized by IboView. (Top to bottom: LUMO+2, LUMO+1, LUMO, HOMO, HOMO-1, HOMO-2)

Charge Distribution (%) of Ground State Bis(benzene)chromium^[18]

		Cr			C			H
Molecular Orbital	No. of Electrons	s	p	d	s	p𝝈	p𝝅	s
4e1g	0			73	2	2	10
3e2u	0						73
4a1g	2	1		82		1	1	1
3e2g	4			50		2	21
3e1g	4			16		1	52
4e1u	4		4				49
2e2u	4					60		17
2e2g	4			1		60		18
4a2u	2		4				61
3a1g	2	8					53

3d orbitals population of chromium(0) in bis(benzene)chromium was investigated, utilizing NBO analysis. While e_2g largely results from electron donation from the metal to the ligand, e_1g is mainly composed of the electrons donated from the benzene ligands.^[13]

3d orbital population of Cr in Bis(benzene)chromium^[13]

Molecular Orbitals	NBO	X-ray
4a1g	1.896/36%	1.62(1)/35%
3e2g	2.412/45%	1.953(7)/42%
3e1g	1.026/19%	1.112(7)/24%

In contrast to ferrocene, where 𝝅-interactions dominate the metal-ligand bonds, 𝞭-interactions play a significant role in bis(benzene)chromium.^[17][18]

Energy Decomposition Analysis at BP86/TZP of Ferrocene and Bisbenzenechromium^[17]

		Ferrocene	Bis(benzene)chromium
Electrostatic Interaction %		51.1	37.9
Covalent Interaction %		48.9	62.1
Contribution to Covalent Interaction %	𝝅-interactions (e1g)	64.7	14.7
	𝞭-interactions (e2g)	8.3	73.4

Reactivity

The compound reacts with carboxylic acids to give chromium(II) carboxylates, such as chromium(II) acetate. Oxidation affords [Cr(C₆H₆)₂]⁺. Carbonylation gives (benzene)chromium tricarbonyl.

In late 1990s, Samuel and coworkers revealed that bis(benzene)chromium is an efficient organometallic radical scavenger. In contrast to cobaltocene, which traps radicals (R^•) to form 18-valence electron species (η⁵-C₅H₅)(η⁴-C₅H₅R)Co, bis(benzene)chromium reacts with radicals to form 17-valence electron species (η⁶-C₆H₆)(η⁵-C₆H₆R)Cr (R = H, D, isobutyronitrile).^[19]

Spin trapping by bis(benzene)chromium (R = H, D, isobutyronitrile)^[19]

Subsequently, bis(benzene)chromium was reported to catalyze hydrosilation of alcohols and aldehydes. Unlike late transition metal-catalyzed processes involving oxidative addition, the mechanism of this reaction is proposed to involve radicals and hydrogen atom abstraction.^[20]

Hydrosilation of ketones catalyzed by bis(benzene)chromium^[20]

The compound finds limited use in organic synthesis.^[21]