Transition metal dinitrogen complexes are

coordination compound A coordination complex is a chemical compound consisting of a central atom or ion, which is usually metallic and is called the ''coordination centre'', and a surrounding array of chemical bond, bound molecules or ions, that are in turn known as ' ...

s that contain

transition metal In chemistry, a transition metal (or transition element) is a chemical element in the d-block of the periodic table (groups 3 to 12), though the elements of group 12 (and less often group 3) are sometimes excluded. The lanthanide and actinid ...

s as ion centers the

dinitrogen Nitrogen is a chemical element; it has symbol N and atomic number 7. Nitrogen is a nonmetal and the lightest member of group 15 of the periodic table, often called the pnictogens. It is a common element in the universe, estimated at seventh ...

molecules (N₂) as

ligand In coordination chemistry, a ligand is an ion or molecule with a functional group that binds to a central metal atom to form a coordination complex. The bonding with the metal generally involves formal donation of one or more of the ligand's el ...

Historical background

Transition metal complexes of N₂ have been studied since 1965 when the first complex was reported by Allen and Senoff. This

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complex, u(NH₃)₅(N₂)sup>2+, was synthesized from hydrazine hydrate and ruthenium trichloride and consists of a u(NH₃)₅sup>2+ centre attached to one end of N₂. The existence of N₂ as a ligand in this compound was identified by IR spectrum with a strong band around 2170–2100 cm⁻¹. In 1966, the molecular structure of u(NH₃)₅(N₂)l₂ was determined by Bottomly and Nyburg by

X-ray crystallography X-ray crystallography is the experimental science of determining the atomic and molecular structure of a crystal, in which the crystalline structure causes a beam of incident X-rays to Diffraction, diffract in specific directions. By measuring th ...

. The dinitrogen complex ''trans''- rCl(N₂)(PPh₃)₂is made by treating Vaska's complex with aromatic acyl azides. It has a planar geometry. The first preparation of a metal-dinitrogen complex using dinitrogen was reported in 1967 by Yamamoto and coworkers. They obtained o(H)(N₂)(PPh₃)₃by reduction of Co(acac)₃ with AlEt₂OEt under an atmosphere of N₂. Containing both hydrido and N₂ ligands, the complex was of potential relevance to nitrogen fixation. From the late 1960s, a variety of transition metal-dinitrogen complexes were made including those with iron, molybdenum and vanadium as metal centers. Interest in such complexes arises because N₂ comprises the majority of the atmosphere and because many useful compounds contain nitrogen. Biological

nitrogen fixation Nitrogen fixation is a chemical process by which molecular dinitrogen () is converted into ammonia (). It occurs both biologically and abiological nitrogen fixation, abiologically in chemical industry, chemical industries. Biological nitrogen ...

probably occurs via the binding of N₂ to those metal centers in the enzyme nitrogenase, followed by a series of steps that involve electron transfer and

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Bonding modes

In terms of its bonding to transition metals, N₂ is related to CO and

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as all three species have

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s. A variety of bonding modes have been characterized. Based on whether the N₂ molecules are shared by two more metal centers, the complexes can be classified into mononuclear and bridging. Based on the geometric relationship between the N₂ molecule and the metal center, the complexes can be classified into end-on or side-on modes. In the end-on bonding modes of transition metal-dinitrogen complexes, the N-N vector can be considered in line with the metal ion center, whereas in the side-on modes, the metal-ligand bond is known to be perpendicular to the N-N vector.

Mononuclear, end-on

As a ligand, N₂ usually binds to metals as an "end-on" ligand, as illustrated by u(NH₃)₅N₂sup>2+. Such complexes are usually analogous to related CO derivatives. This relationship is illustrated by the pair of complexes IrCl(CO)(PPh₃)₂ and IrCl(N₂)(PPh₃)₂. In these mononuclear cases, N₂ is both as a σ-donor and a π-acceptor. The M-N-N bond angles are close to 180°. N₂ is a weaker pi-acceptor than CO, reflecting the nature of the π* orbitals on CO vs N₂. For this reason, few examples exist of complexes containing ''both'' CO and N₂ ligand. Transition metal-dinitrogen complexes can contain more than one N₂ as "end-on" ligands, such as ''mer''- o(N₂)₃(PPr''ⁿ''₂Ph)₃ which has octahedral geometry. In another example, the dinitrogen ligand in Mo(N₂)₂(Ph₂PCH₂CH₂PPh₂)₂ can be reduced to produce ammonia. Because many nitrogenases contain Mo, there has been particular interest in Mo-N₂ complexes.

Bridging, end-on

N₂ also serves as a bridging ligand with "end-on" bonding to two metal centers, as illustrated by ⁴⁺. These complexes are also called multinuclear dinitrogen complexes. In contrast to their mononuclear counterpart, they can be prepared for both early and late transition metals. In 2006, a study of iron-dinitrogen complexes by Holland and coworkers showed that the N–N bond is significantly weakened upon complexation with iron atoms with a low coordination number. The complex involved bidentate chelating ligands attached to the iron atoms in the Fe–N–N–Fe core, in which N₂ acts as a bridging ligand between two iron atoms. Increasing the coordination number of iron by modifying the chelating ligands and adding another ligand per iron atom showed an increase in the strength of the N–N bond in the resulting complex. It is thus suspected that Fe in a low-coordination environment is a key factor to the fixation of nitrogen by the nitrogenase enzyme, since its Fe–Mo cofactor also features Fe with low coordination numbers. The average bond length of those bridging-end-on dinitrogen complexes is about 1.2 Å. In some cases, the bond length can be as long as 1.4 Å, which is similar to those of N-N single bonds. Hasanayn and co-workers have shown that the Lewis structures of end-on bridging complexes can be assigned based on π-molecular-orbital occupancy, in analogy with simple tetratomic organic molecules. For example the cores of N₂-bridged complexes with 8, 10, or 12 π-electrons can generally be formulated, respectively, as M≡N-N≡M, M=N=N=M, and M-N≡N-M, in analogy with the 8-, 10-, and 12-π-electron organic molecules HC≡C-C≡CH, O=C=C=O, and F-C≡C-F.

Mononuclear, side-on

In comparison with their end-on counterpart, the mononuclear side-on dinitrogen complexes are usually higher in energy and the examples of them are rare. Dinitrogen act as a π-donor in these types of complexes. Fomitchev and Coppens has reported the first crystallographic evidence for side-on coordination of N₂ to a single metal center in a photoinduced metastable state. When treated with UV light, the transition metal-dinitrogen complex, s(NH₃)₅(N₂)sup>2+ in solid states can be converted into a metastable state of s(NH₃)₅(η²-N₂)sup>2+, where the vibration of dinitrogen has shifted from 2025 to 1831 cm⁻¹. Some other examples are considered to exist in the

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s of intramolecular linkage isomerizations. Armor and Taube has reported these isomerizations using ¹⁵N-labelled dinitrogen as ligands.

Bridging, side-on

In a second mode of bridging, bimetallic complexes are known wherein the N-N vector is perpendicular to the M-M vector, which can be considered as side-on fashion. One example is η⁵-C₅Me₄H)₂Zrsub>2( μ₂, η²,η²-N₂). The dimetallic complex can react with H₂ to achieve the artificial

by reducing N₂. A related ditantalum tetrahydride complex could also reduce N₂.

Reactivity

Cleavage to nitrides

When metal nitrido complexes are produced from N2, the intermediacy of a dinitrogen complex is assumed. Some Mo(III) complexes also cleave N₂: :2Mo(NR₂)₃ + N₂ → (R₂N)₃Mo-N₂-Mo(NR₂)₃ :(R₂N)₃Mo-N₂-Mo(NR₂)₃ → 2N≡Mo(NR₂)₃

Attack by electrophiles

Some electron-rich metal dinitrogen complexes are susceptible to attack by electrophiles on nitrogen. When the electrophile is a proton, the reaction is of interest in the context of abiological nitrogen fixation. Some metal-dintrogen complexes even catalyze the hydrogenation of N₂ to

ammonia Ammonia is an inorganic chemical compound of nitrogen and hydrogen with the chemical formula, formula . A Binary compounds of hydrogen, stable binary hydride and the simplest pnictogen hydride, ammonia is a colourless gas with a distinctive pu ...

in a cycle that involves N-protonation of a reduced M-N₂ complex.

References

{{reflist, 35em Coordination complexes Nitrogen compounds