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Methyllithium

Methyllithium (CH₃Li) is the simplest organolithium compound, an s-block organometallic reagent characterized by a highly polar lithium-carbon bond and oligomeric structures in both solid and states. This pyrophoric, air- and moisture-sensitive substance reacts violently with to evolve flammable gases and is typically handled as a in ethers or hydrocarbons. First synthesized in 1917 by Wilhelm Schlenk and Johanna Holtz through transmetalation of dimethylmercury with lithium, methyllithium is now commonly prepared via the Ziegler process, involving the reaction of lithium metal with methyl chloride in a hydrocarbon solvent, often resulting in minor lithium chloride contamination. In organic synthesis, it serves as a strong base for deprotonation of weak carbon acids and as a methyl anion source for nucleophilic additions to carbonyls, forming carbon-carbon bonds in the construction of complex molecules. Additionally, methyllithium functions as a , polymerization initiator for anionic processes, and partner to generate other organometallics, with its reactivity influenced by aggregation state and . Due to its extreme reactivity and corrosiveness, strict protocols are required, including inert atmospheres and specialized glassware to prevent ignition or .

Synthesis

Laboratory Preparation

Methyllithium is typically prepared in the laboratory through the direct reaction of lithium metal with a methyl halide in anhydrous diethyl ether under an inert atmosphere, a method pioneered by Henry Gilman and coworkers in the 1930s. The reaction with methyl bromide or methyl iodide is most common, proceeding according to the equation: $2 \mathrm{Li} + \mathrm{CH_3Br} \rightarrow \mathrm{CH_3Li} \cdot \mathrm{LiBr} This generates methyllithium as a soluble complex with in the solvent. The procedure requires finely dispersed (often 1% sodium-activated) and controlled addition of the halide gas or solution to manage the , typically at temperatures around 25°C. Yields range from 70% to 90%, depending on the purity of reagents and reaction scale. An alternative method employs with excess metal to produce a lower-halide product, leveraging the relative insolubility of for partial separation during the reaction. In this approach, gas is bubbled into a suspension of lithium dispersion in under , followed by stirring and settling to precipitate LiCl. This variant minimizes impurities from bromide or iodide, achieving concentrations of 1.4–1.8 M methyllithium with 0.07–0.09 M residual LiCl, corresponding to 70–89% yields. Purification to obtain halide-free methyllithium involves treating the crude with dioxane, which forms an insoluble LiX·dioxane (where X is or ) that can be removed by under inert conditions. The filtrate yields a purer methyllithium suitable for sensitive applications, with the process conducted at low temperatures to preserve stability. All preparations demand rigorous exclusion of moisture and oxygen to prevent .

Commercial Production

Methyllithium is produced on an industrial scale primarily through the direct reaction of metal with in an or aromatic system, yielding a of the along with as a . The process involves dispersing metal (often alloyed with small amounts of sodium for improved reactivity) in a such as or containing methyltetrahydrofuran as a solubilizing additive, followed by the controlled addition of gaseous or liquid at temperatures around 40–45°C to manage the . The simplified reaction is given by: $2 \mathrm{Li} + \mathrm{CH_3Cl} \rightarrow \mathrm{CH_3Li} + \mathrm{LiCl} After reaction completion, the insoluble lithium chloride is filtered out under inert conditions, producing a clear solution suitable for packaging and distribution. Major commercial suppliers of methyllithium include Albemarle Corporation and producers such as Ganfeng Lithium Group and Neogen Chemicals (as of 2025), which manufacture the reagent as stabilized solutions in ethers, typically at concentrations of 1.5–3 M in diethyl ether, diethoxymethane, or cumene to prevent decomposition and ensure safe handling. These producers emphasize low-halide variants, achieved through efficient filtration or specialized solvent systems, to meet purity requirements for sensitive applications in organic synthesis. Global production of methyllithium dates back to the , coinciding with the expansion of and increasing demand for strong nucleophilic and basic reagents in pharmaceutical and industries; output remains closely tied to this market. Key economic factors influencing availability include the sourcing of high-purity metal, derived from ore processing or extraction, which accounts for a significant portion of costs due to fluctuating prices and energy-intensive . Additionally, and of volatile solvents during and purification steps are critical for cost efficiency, as these solvents represent another major expense in large-scale operations.

Structure and Bonding

Solid-State Structure

Methyllithium adopts a tetrameric structure, (LiCH₃)₄, in the solid state, characterized by a cubane-like [Li₄C₄] core where four atoms occupy alternate corners of a distorted , interlaced with four methyl carbon atoms. Each carbon bridges three atoms in a μ₃-coordination mode, resulting in for the lithium framework and no direct carbon-carbon bonds. powder studies from the 1970s confirmed close Li-C contacts, with average C-Li s of 2.31 and Li-Li distances of 2.68 , comparable to the Li-Li in gas (2.67 ). These metrics highlight the electron-deficient nature of the cluster, stabilized by multicenter involving the 3-center-2-electron interactions across Li₃C faces. The tetrameric arrangement was initially determined through early crystallographic analyses in the and refined using powder data in 1970, establishing the body-centered cubic (a = 7.24 Å, I4̅3m) containing two formula units per cell. Subsequent theoretical optimizations in the corroborated the experimental geometry, revealing a staggered conformation of the methyl groups relative to the Li₃C planes, driven by electrostatic stabilization within the tetramer. This conformation contrasts with eclipsed arrangements observed in some gas-phase or computational models. Recent studies have isolated monomeric methyllithium complexes using specialized hexadentate ligands, revealing short C-Li bond lengths around 2.09 . The preferred oligomeric structure in the solid state is influenced by the crystallization solvent, with promoting the tetrameric form due to its ability to solvate centers without disrupting the cluster integrity during precipitation or evaporation.

Solution and Bonding Characteristics

Methyllithium exhibits electron-deficient bonding in its oligomeric forms, characterized by three-center two-electron (3c-2e) interactions that delocalize across carbon-lithium bridges, contributing to the stability of dimers and tetramers. The C-Li is approximately 57 kcal/mol in the dimeric form, reflecting significant covalent character despite the ionic contributions from 's electropositivity. This multicentered bonding model arises from the overlap of carbon sp³ orbitals with lithium 2s orbitals, forming electron-deficient bridges that lower the overall energy compared to monomeric structures. In ethereal solvents such as or (THF), methyllithium maintains a among tetramers, dimers, and monomers, with the dominant species depending on concentration and . At higher concentrations in , tetramers predominate, while dilution or addition of chelating ligands like N,N,N',N'-tetramethylethylenediamine (TMEDA) shifts the equilibrium toward bis-solvated dimers or even monomers, enhancing reactivity by reducing aggregation. This solvent-dependent behavior stems from coordination of ether oxygen atoms to lithium centers, which competes with intermolecular Li-C interactions and disrupts higher-order aggregates. The solution structures observed parallel the oligomeric motifs in the solid state, providing a basis for understanding dynamic interconversions. Nuclear magnetic resonance (NMR) offers key insights into these solution aggregates. In ⁷Li NMR spectra, tetrameric display chemical shifts around 1.0–2.0 , reflecting the deshielded environment of in the tetrahedral core, whereas dimers appear upfield at approximately -1 to -2 due to increased . The ¹³C NMR signals for the methyl carbons show one-bond C-Li coupling constants of about 20 Hz in aggregated forms, indicative of partial s-character in the bridging bonds and distinguishing them from the larger couplings (>100 Hz) expected for free monomers. Density functional theory (DFT) calculations corroborate the multicentered bonding framework, modeling the oligomers as networks of 3c-2e interactions with hyperconjugative contributions from C-H bonds stabilizing conformations. These computations reveal that explicit by molecules preferentially stabilizes lower aggregates by donating to , thereby reducing oligomerization energies and aligning with experimental NMR observations.

Reactivity

Nucleophilic Reactions

Methyllithium serves as a potent in carbon-carbon bond-forming reactions, particularly through its addition to electrophilic centers. One of the most common applications is its reaction with carbonyl compounds, where the methyl anion attacks the carbonyl carbon, forming a intermediate that, upon aqueous , yields the corresponding . For instance, the addition to ketones produces alcohols, as illustrated by the reaction of methyllithium with : \mathrm{(C_6H_5)_2C=O + CH_3Li \rightarrow (C_6H_5)_2C(OLi)CH_3 \xrightarrow{H_3O^+} (C_6H_5)_2C(OH)CH_3} This process is highly efficient due to the strong nucleophilicity of the , which proceeds via a four-center involving the monomeric or dimeric form of methyllithium coordinating to the oxygen. Compared to Grignard reagents, methyllithium exhibits greater reactivity toward carbonyls, attributed to the higher polarity of the carbon- bond and reduced coordination by , allowing faster addition rates even at lower temperatures. Methyllithium also engages in with alkyl halides, potentially forming higher homologues or products by displacing the halide ion. For example, it reacts with to afford through sequential methylations: \mathrm{PCl_3 + 3 CH_3Li \rightarrow P(CH_3)_3 + 3 LiCl} However, these reactions are often complicated by side processes, including elimination due to the strong basicity of methyllithium, which can deprotonate beta-hydrogens in the alkyl halide, leading to alkenes instead of clean products. This limitation is particularly pronounced with secondary or alkyl halides, where single-electron pathways may compete, reducing yields of the desired . A straightforward nucleophilic reaction involves with , where methyllithium adds to the electrophilic carbon of CO₂ to form directly: \mathrm{CH_3Li + CO_2 \rightarrow CH_3CO_2Li} This transformation is quantitative under conditions and exemplifies the utility of organolithiums in introducing functionality after acidic workup. In additions to aldehydes bearing α-coordinating groups, such as alkoxy substituents, methyllithium often proceeds under control, where the lithium cation bridges the carbonyl oxygen and the α-heteroatom, forming a five-membered ring intermediate. This rigidifies the , directing nucleophilic attack from the face opposite the α-substituent and favoring the Cram chelate with high selectivity (typically >10:1 diastereomeric ratio). Such control overrides non-chelated Felkin-Anh pathways, enabling predictable stereochemical outcomes in synthesis of 1,2-diols.

Basicity and Other Reactions

Methyllithium exhibits strong basicity due to the high pKa of its conjugate acid, , estimated at approximately 48–50 in ethereal solvents. This property enables it to deprotonate weak carbon acids with pKa values around 25, such as terminal alkynes, generating lithium acetylides and as a byproduct. For instance, the reaction proceeds as follows: \ce{CH3Li + RC#CH -> RC#CLi + CH4} This deprotonation is typically conducted in anhydrous ether solvents at low temperatures to control the exothermic process and prevent side reactions. Beyond acid-base chemistry, methyllithium reacts with nonmetal halides to substitute halogens with methyl groups, forming organometallic or organic compounds. A representative example involves phosphorus trichloride, where three equivalents of methyllithium convert the halide to trimethylphosphine and lithium chloride. The reaction is carried out at low temperature, such as -78°C, in ether, yielding up to 60% of the phosphine product under optimized conditions. Similar halogen-metal exchanges occur with other nonmetal halides like those of silicon or boron, though yields and selectivity depend on the substrate. Methyllithium also participates in transmetalation reactions with transition metal salts, transferring the methyl group to form more stable organometallic species. This is exemplified in the synthesis of Gilman reagents (lithium dialkylcuprates), where two equivalents of methyllithium react with copper(I) iodide to produce lithium dimethylcuprate and lithium iodide. The process, first described by Henry Gilman, involves: \ce{2 CH3Li + CuI -> (CH3)2CuLi + LiI} These cuprates are milder nucleophiles than organolithiums and are widely used in selective carbon-carbon bond formations. In protic environments, methyllithium undergoes rapid decomposition, reacting violently with to liberate , form , and release substantial heat (comparable to -226 kJ/mol for analogous alkyllithiums). The reaction equation is: \ce{CH3Li + H2O -> CH4 + LiOH} This exothermic process generates flammable gases that can ignite spontaneously, necessitating strict conditions for handling. Alcohols elicit similar violent responses, underscoring methyllithium's incompatibility with protic solvents.

Applications

Organic Synthesis Uses

Methyllithium serves as a versatile in , particularly for introducing methyl groups through nucleophilic additions and , offering advantages in selectivity and reactivity over milder organometallics. Its high nucleophilicity enables efficient transformations in sensitive substrates, such as the preparation of Wittig reagents by of salts. For instance, treatment of appropriate halides with methyllithium generates the corresponding ylides, which are then employed in olefination reactions to form alkenes from carbonyl compounds. In the formation of enolates, methyllithium acts as a strong, when used in controlled equivalents, deprotonating carbonyl compounds or their derivatives to generate enolates for subsequent . This approach is particularly useful for regioselective enolate formation in unsymmetrical , where methyllithium's basicity allows clean at low temperatures, minimizing over- or side reactions. A notable involves the reaction of enol acetates with two equivalents of methyllithium, yielding enolates alongside lithium tert-butoxide, facilitating further synthetic manipulations. Methyllithium is widely applied in the synthesis of pharmaceutical intermediates, including those for and , by selectively adding methyl groups to complex scaffolds. In steroid chemistry, it adds to functionalities in precursors like cholestanone derivatives, enabling the construction of side-chain modifications essential for biologically active compounds such as oxysterols. For example, deuterated methyllithium has been used to introduce isotopically labeled methyl groups in 25-hydroxycholesterol synthesis, aiding pharmacokinetic studies. Similarly, in alkaloid , methyllithium facilitates steps in polycyclic frameworks, enhancing molecular diversity in analogs. Compared to Grignard reagents, methyllithium exhibits greater reactivity due to the more ionic lithium-carbon bond, allowing reactions to proceed at lower temperatures such as -78°C, which suppresses unwanted side products like enolization or elimination in sensitive electrophiles. This enhanced reactivity is particularly beneficial in nucleophilic additions to hindered carbonyls or imines, where Grignard reagents may require harsher conditions, leading to lower yields. The ability to operate under cryogenic conditions with methyllithium provides superior control in stereoselective syntheses, as the lower energy barrier reduces competing pathways. In , methyllithium initiates of monomers like styrene and 1,3-butadiene, producing narrow molecular polymers with controlled end-group functionality. As a primary initiator, it generates a carbanionic chain end that propagates efficiently in solvents, yielding styrenic homopolymers or copolymers used in high-performance elastomers. The use of methyllithium ensures high efficiency, often exceeding 95%, and compatibility with polar additives for microstructure control in the resulting segments.

Industrial and Specialized Applications

Methyllithium plays a role in polymer synthesis as an anionic initiator for the production of synthetic rubbers from dienes such as and , enabling the formation of materials with tailored microstructures for industrial applications like . Its reactivity allows for precise control over chain length and , contributing to high-performance elastomers used in automotive and consumer products. In , methyllithium is utilized in the re-lithiation of degraded during processes. By reacting with lithium-deficient electrodes, such as those from end-of-life nickel-manganese-cobalt oxides, it restores content to near-original levels (e.g., up to 90-95% recovery), enhancing the capacity and of recycled components without full breakdown. Methyllithium also serves as a key in the preparation of organometallic precursors for doping. It facilitates the synthesis of lithium amidinate salts from lanthanide trichlorides and carbodiimides, which are then used to deposit rare-earth-doped films via , improving the electrical and optical properties of thin-film transistors and optoelectronic devices.

Safety and Handling

Hazards and Risks

Methyllithium exhibits extreme , igniting spontaneously upon exposure to air as a result of rapid oxidation that produces (Li₂CO₃) and hydrocarbons such as . This compound engages in violent exothermic reactions with and alcohols, generating gas and posing risks of due to the rapid release of flammable products. It also reacts exothermically with CO₂ to form . Methyllithium is highly corrosive to and eyes, classified with an oral LD50 greater than 500 mg/kg, reflecting moderate ; exposure may release ions, potentially contributing to systemic toxicity including cardiac effects, while of associated vapors leads to respiratory irritation. Under the Globally Harmonized System (GHS), methyllithium is classified as a pyrophoric (Category 1), a substance which in contact with emits flammable gases (Category 1), (Category 1 or 2 depending on solvent), and causes severe burns and eye damage (Category 1B), accompanied by pictograms for (indicating flammability and pyrophoricity) and (indicating and eye damage).

Storage and Precautions

Methyllithium, being highly pyrophoric and reactive with air and moisture, must be stored under an inert atmosphere such as argon or nitrogen to prevent spontaneous ignition or decomposition. Storage containers should be tightly sealed, dry, and placed in a cool environment, typically at 2-8°C, in a well-ventilated area away from heat sources, sparks, open flames, and incompatible materials like water, acids, or oxidizing agents. It is classified as a pyrophoric liquid (storage class 4.2), requiring locked storage to restrict access and minimize exposure risks. Handling precautions emphasize operations in a or glove box to avoid of vapors or aerosols and with or eyes. Personnel should wear flame-retardant antistatic clothing, gloves (0.4 mm thickness, breakthrough time ≥30 minutes), safety goggles, and face shields. Containers must be opened carefully under to prevent air ingress, and any transfer or use should exclude or humid conditions, as methyllithium reacts violently to produce flammable gases like . Spills require immediate containment with dry sand or inert absorbent, followed by disposal as , while avoiding drains to prevent hazards. Environmental precautions include preventing release into waterways or , as methyllithium's water-reactive nature can generate flammable vapors and pose risks during cleanup. In case of , use dry chemical, sand, or alcohol-resistant extinguishers; or CO2 should be avoided due to enhanced reactivity. Emergency response involves immediate medical attention for exposure, with poison control consultation, and evacuation if large quantities are involved.

First Aid Measures

For skin contact, remove contaminated clothing and rinse affected area with plenty of water; seek medical attention. For eye contact, rinse immediately with water for at least 15 minutes, removing contact lenses if present, and seek immediate medical advice. For inhalation, move to fresh air and provide oxygen if breathing is difficult; seek medical attention. For ingestion, rinse mouth and do not induce vomiting; seek immediate medical attention.