Organometallic Compounds: Definition, Structure, Examples, Properties, Types, Uses, Stability & Reactivity, Application | CollegeSearch

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Organometallic Compounds: Definition, Structure, Examples, Properties, Types, Uses, Stability & Reactivity, Application

Kasturi Talukdar

Updated on 24th July, 2023 , 8 min read

Organometallic Compounds Overview

Organometallic compounds are chemical compounds characterized by a covalent metal-carbon linkage, where the carbon is part of an organic molecule. These compounds are not limited to traditional metals; metalloid elements like tin, silicon, and boron also form organometallic compounds, which find extensive use in various industrial chemical reactions. Some examples of organometallic compounds include tetracarbonyl nickel, Grignard reagent, and dimethyl magnesium. The branch of chemistry dedicated to the study of these substances is known as Organometallic Chemistry.

What are Organometallic Compounds?

Organometallic compounds are a fascinating class of chemical compounds that contain direct metal-carbon (M-C) bonds. They are chemical compounds that exhibit at least one chemical linkage between a carbon atom from an organic molecule and a metal atom. The metals involved can include alkali and transition metals, as well as metalloids. These compounds are also referred to as organyl compounds, and their names are typically prefixed with "organo."

  1. The key defining feature of organometallic compounds lies in the highly covalent metal-carbon bond they possess.
  2. The majority of organometallic compounds are solid at room temperature, although some exceptions, like methylcyclopentadienyl manganese tricarbonyl, exist in liquid form.
  3. Due to the covalent nature of the bond, organometallic compounds formed with metals of high electropositivity, such as lithium and sodium, demonstrate a carbanionic nature in the carbon atom bound to the central metal atom.
  4. Organometallic compounds play a crucial role in catalyzing reactions involving target molecules like polymers or pharmaceuticals, significantly increasing the reaction rate.

Structure of Organometallic Compounds

The structure of organometallic compounds is characterized by the presence of metal atoms or metal clusters bonded to carbon atoms in organic ligands. These carbon atoms can be part of various organic moieties, such as alkyl, aryl, or even more complex functional groups. The nature of the metal-carbon bond can vary, with some compounds featuring ionic bonds, while others exhibit covalent bonds.

Metal carbonyl organometallic compounds adhere to the 18-electron rule, which proves highly effective in predicting their stability. However, some other types of organometallic compounds deviate from this rule and do not follow the 18-electron configuration. Let's explore the 18-electron rule in brief.

The 18-Electron Rule: In compounds, the central metal atom forms bonds by accepting electrons into its orbitals. It can accommodate electrons in its s, p, and d orbitals. Following the 18-electron rule, the central metal atom can hold a maximum of:

  • 2 electrons in the s orbital
  • 6 electrons in the p orbital
  • 10 electrons in the d orbital

Hence, the total electron count becomes:

s(2) + p(6) + d(10) = 18 electrons

This is known as the 18-Electron Rule or the Effective Atomic Number (EAN).

The primary objective of the 18-electron rule is to achieve the nearest noble gas configuration for the central metal atom. By ensuring that the total number of d-electrons (i.e., the outermost electrons of transition elements) and the electrons contributed by ligands sum up to 18, the valence shell of the metal attains stability with 18 electrons.

Examples of Organometallic Compounds

These examples represent only a small fraction of the diverse and numerous organometallic compounds that exist in chemistry. Organometallic chemistry plays a significant role in various fields, including catalysis, organic synthesis, materials science, and pharmaceutical research.

  1. Grignard Reagent: Alkyl or aryl magnesium halides, such as methylmagnesium chloride (CH3MgCl), ethylmagnesium bromide (C2H5MgBr), etc.
  2. Ferrocene: A sandwich-like compound consisting of a cyclopentadienyl anion (Cp-) and an iron (Fe2+) cation, denoted as (C5H5)2Fe.
  3. Zeise's Salt: An organometallic complex containing a platinum (Pt) metal center and an ethylene ligand (C2H4), with a chemical formula K[PtCl3(C2H4)]·H2O.
  4. Wilkinson's Catalyst: A rhodium (Rh) complex with the formula RhCl(PPh3)3, used as a hydrogenation catalyst.
  5. Methylcobalamin: A biologically active form of vitamin B12, containing a cobalt (Co) metal center coordinated to a methyl group (CH3) and other ligands.
  6. Tetracarbonyl Nickel: An organometallic compound with the formula Ni(CO)4, widely used in catalysis and as a precursor for other nickel carbonyl complexes.
  7. Cyclopentadienyliron Dicarbonyl Dimer: Also known as "Fp2" or "Fe2(CO)9," it is an iron (Fe) compound used in organic synthesis and as a starting material for other organometallic reactions.
  8. Trimethylaluminum: An organometallic compound with the formula Al(CH3)3, used as a co-catalyst in Ziegler-Natta polymerization reactions.
  9. Titanocene Dichloride: A metallocene compound with the formula (C5H5)2TiCl2, used in various catalytic reactions.
  10. Triphenylphosphine Copper (I) Iodide: An organometallic complex with the formula CuI(PPh3)3, utilized in coupling reactions like the famous Heck reaction.
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Properties of Organometallic Compounds

Organometallic compounds display a diverse array of properties, making them versatile and intriguing subjects of study. Some key properties include:

  1. State: These compounds are typically found in solid form, particularly when they contain aromatic or ring-structured hydrocarbon groups. However, some organometallic compounds can also exist as liquids.
  2. Solubility: Organometallic compounds are generally insoluble in water but exhibit solubility in organic solvents like ether.
  3. Metal-Carbon Bond: The metal-carbon bond in organometallic compounds is highly covalent, contributing to their unique properties.
  4. Reactivity: Organometallic compounds are exceptionally reactive and are thus stored in organic solvents to prevent unwanted reactions.
  5. Electronegativity: In organometallic compounds, the carbon atom typically has an electronegativity of 2.5, whereas most metals have lower electronegativity values, usually less than 2.
  6. Reducers: Organometallic compounds formed by electropositive metals serve as effective reducing agents in various chemical reactions.
  7. Spontaneous Combustion: Compounds containing highly electropositive metals like lithium and sodium can be extremely volatile and may spontaneously catch fire.
  8. Toxicity: Some organometallic compounds, especially volatile ones, have been reported to exhibit toxicity to humans.

Stability and Reactivity of Organometallic Compounds

The stability of organometallic compounds is influenced by several factors, including the nature of the metal, the type of ligands, and the coordination geometry. Transition metals are commonly used in organometallic complexes due to their variable oxidation states, facilitating redox reactions. Ligands can be classified as σ-donors, π-donors, and π-acceptors, affecting the overall stability and reactivity of the compound.

The stability and reactivity characteristics of organometallic compounds can be described as follows:

Stability:

  1. The stability of organometallic compounds relies on the type of metal bonded to the organic ligand.
  2. In the periodic table, the thermal stability of these compounds decreases as we move from the lightest to the heaviest elements in groups 1, 2, and 13-15. This decline in thermal stability is attributed to the weakening of the metal-carbon bond strength as we move down the groups in the periodic table. 
  3. In contrast, for d-block elements in groups 3-12, the metal-carbon bond strength and overall stability increase as we descend the group.

Reactivity: 

  1. Organometallic compounds exhibit considerable reactivity when exposed to water or air.
  2. Main-group metals, such as Li, Na, Mg, Al, and others, are highly reactive and sensitive to air or water. A classic example is Al2(CH3)6, which rapidly reacts with water, leading to the release of methane gas. This gas can ignite when in contact with air, resulting in a flame. 
  3. On the other hand, elements in groups 14 and 15, such as tetramethylsilicon, are unreactive with water or air, remaining inert at room temperature.

Classification of Organometallic Compounds

Organometallic compounds can be broadly classified into several categories based on their structural features and bonding characteristics:

  • Main Group: Comprising metals from the s or p-block, with a prominent example being the Grignard reagent, R-Mg-X.
  • Transition Metal: Consisting of d-block metals, exemplified by compounds like Pd(PPh3)4 and R2CuLi (Gillman's Reagent).
  • Lanthanide and Actinide: Incorporating f-block metals, with Uranocene serving as an example of such organometallic compounds.

Regarding the type of bond, organometallic compounds can be classified into the following three types:

  1. Sigma Bonded: Formed when the metal atom and carbon atom of the ligand are connected by a sigma bond. For instance, Grignard reagents (R-Mg-X), where R represents an alkyl or aryl group and X denotes a halogen, as well as zinc compounds with the formula R2Zn, like (C2H5)2Zn, as isolated by Frankland.
  2. Pi-Bonded: Comprising compounds of metals with alkenes, alkynes, benzene, and other ring compounds. In these complexes, the metal and ligand form a bond that involves the π-electrons of the ligand. Prominent examples include Zeise's salt, ferrocene, and di benzene chromium. The number of carbon atoms bonded to the metal in these compounds is indicated by the Greek letter η (eta) followed by a number, such as η2, η5, and η6, signifying 2, 5, and 6 carbon atoms bonded to the metal, respectively.
  3. Sigma and Pi Bonded: Representing metal carbonyl compounds formed between the metal and carbon monoxide, with a combination of σ-and π-bonding. Generally, the oxidation state of metal atoms in these compounds is zero. Carbonyls may be mononuclear, bridged, or polynuclear. Notable examples include Ni(CO)4, Fe(CO)5, Cr(CO)6, and Fe(CO)9.

Uses of Organometallic Compounds

The significance of organometallic compounds cannot be emphasized enough, as advancements in this field have led to the development of novel synthesis reagents and catalysts. Organometallic compounds find diverse applications, including:

  1. Homogeneous Catalysis: Many processes in solution are catalyzed by organometallic compounds or intermediates derived from transition metal complexes.
  2. Metal Purification: Impure metals can be converted into carbonyls, which are then decomposed to obtain pure metal.
  3. Organic Synthesis: Organometallic compounds, such as organolithium and organomagnesium compounds, are frequently employed in the synthesis of various organic compounds.
  4. Heterogeneous Catalysis: Combinations like trialkyl aluminum with a transition metal halide (e.g., titanium trichloride or tetrachloride) serve as heterogeneous catalysts for alkane polymerization at low temperatures.
  5. Agriculture: Organometallics like ethyl mercury chloride are used to treat seeds, protecting immature plants from infections.
  6. Medicine: Organometallic chemicals, particularly organoarsenic compounds, are employed as a primary treatment for syphilis. Additionally, silicone rubbers derived from organometallic compounds are utilized as body spare parts in modern surgery.

Application of Organometallic Compounds

Organometallic compounds find extensive applications in various fields, and some of their uses are highlighted below:

  1. Reagents: Organometallic compounds serve as valuable reagents in chemical reactions.
  2. Hydrogenation Catalyst: Wilkinson's catalyst is employed in the hydrogenation of alkenes.
  3. Polymerization Catalyst: The Ziegler-Natta catalyst [(C2H5)3AlTiCl4] is utilized for the polymerization of alkenes.
  4. Syphilis Treatment: Organoarsenic compounds are used in the treatment of syphilis.
  5. Coupling Reactions: Palladium catalysts are instrumental in coupling reactions.
  6. Synthesis of Compounds: The Grignard reagent is employed in the synthesis of various compounds, including secondary alcohols and aldehydes.
  7. Industrial Applications: Organometallic compounds find a wide range of industrial applications. For example, organolithium compounds are highly basic and are thus valuable in many stoichiometric polymerization reactions.
  8. Drug Use: The organometallic compound Cp2TiCl2 (Cp representing cyclopentadienyl anion) is utilized as a drug.
  9. Anticancer Drug: Cis-Platin is used as an anticancer drug.
  10. Additives: Organometallic compounds are employed as additives, with TEL (Tetraethyl lead) serving as an anti-knocking agent in fuels.

Organometallic Compounds: Things to Remember

  1. Organometallic compounds consist of organic molecules that form covalent carbon-metal linkages.
  2. The formation and structure of organometallic compounds are dictated by the 18-electron rule.
  3. Organometallic compounds exhibit reducing properties, promote spontaneous combustion, and are known for their toxic nature.
  4. The thermal stability and reactivity of organometallic compounds rely on the strength of the carbon-metal bonds.
  5. Organometallic compounds are broadly classified into main group, transition metal, lanthanide, and actinide categories.
  6. Depending on the nature of the bond, organometallic compounds are categorized as sigma bonded, pi bonded, or a combination of both.
  7. Organometallic compounds find extensive applications as stoichiometric catalysts, in the production of semiconductors, and LEDs.
  8. Many organometallic compounds exhibit reactivity resulting from bond polarity, making them valuable tools in chemical synthesis

Frequently Asked Questions

What are organometallic compounds?

Organometallic compounds are chemical compounds containing at least one metal-carbon bond. They consist of organic ligands (containing carbon) coordinated to a metal atom.

How are organometallic compounds prepared?

Organometallic compounds can be prepared through various methods, such as the reaction of metal halides with organolithium or Grignard reagents, or by oxidative addition of metals to organic substrates.

What is the significance of organometallic compounds?

Organometallic compounds play a crucial role in catalysis, organic synthesis, and materials science. They find applications in pharmaceuticals, agriculture, and various industrial processes.

Are organometallic compounds toxic?

Some organometallic compounds can be toxic due to the presence of heavy metals. Proper handling and disposal measures are essential to avoid health and environmental hazards.

What is the 18-electron rule in organometallic chemistry?

The 18-electron rule states that stable organometallic compounds often have 18 valence electrons around the metal center. This rule influences the stability and reactivity of these compounds.

Can you provide examples of organometallic catalysts?

Examples of organometallic catalysts include Wilkinson's catalyst (RhCl(PPh3)3) for hydrogenation and Ziegler-Natta catalysts for olefin polymerization.

How do organometallic compounds act as reducing agents?

Organometallic compounds can undergo oxidative addition or single-electron transfer reactions, enabling them to donate electrons and act as reducing agents.

What are some common applications of organometallic compounds in industry?

Organometallic compounds are widely used as catalysts in industrial processes, particularly in the production of plastics, pharmaceuticals, and fine chemicals.

Can you explain the differences between sigma and pi bonded organometallic compounds?

Sigma bonded compounds have a direct head-on overlap of orbitals, while pi bonded compounds have a side-to-side overlap of orbitals. Pi bonded compounds often involve π-electron delocalization.

How do organometallic compounds contribute to sustainable chemistry?

Organometallic catalysis enables more efficient and selective reactions, reducing waste and energy consumption, thus contributing to greener and more sustainable chemical processes.

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