Fact-checked by Grok 2 weeks ago

Nitromethane

Nitromethane (CH₃NO₂) is a simple consisting of a attached to a nitro group, appearing as a colorless, oily with a disagreeable . It is slightly soluble in and denser than , with key physical including a of 101.1°C, a of -28.5°C, a of 1.1371 g/cm³ at 20°C, and a of 35°C. Chemically, it serves as a and a strong , capable of forming explosive mixtures with air at concentrations as low as 7.3%. Nitromethane is commercially produced via high-temperature vapor-phase of with , a process first developed after its initial synthesis in 1872. Its primary industrial uses include as a for esters, adhesives, and coatings. In motorsports, particularly , it is blended into fuels to enhance power output due to its oxygen-rich structure, which supports more complete . Additionally, it acts as a chemical in the production of pharmaceuticals, pesticides, explosives, fibers, and coatings. Due to its reactivity, nitromethane poses significant safety hazards, including flammability ( of 417°C) and potential for when heated, shocked, or mixed with acids, bases, or amines. It irritates the skin, eyes, and , and prolonged may lead to or allergic dermatitis; it is classified as possibly carcinogenic to humans (Group 2B) based on showing increased tumor incidence. Occupational exposure limits include an OSHA PEL-TWA of 100 and an ACGIH TLV-TWA of 20 , with an IDLH value of 750 . Handling requires protective equipment, such as chemical-resistant gloves and suits, and storage away from incompatibles to prevent violent reactions.

Properties

Physical properties

Nitromethane has the molecular formula CH₃NO₂ and a molecular weight of 61.04 g/mol. It appears as a colorless, oily with a disagreeable . The compound exhibits a of -29.0 °C and a of 101.2 °C at standard . At 20 °C, nitromethane has a of 1.137 /cm³ and a dynamic of 0.65 , contributing to its fluid handling characteristics. Its solubility in water is 12.5 /100 mL at 20 °C, while it is miscible with most organic solvents such as and acetone. The is 1.381 (at 20 °C), and the is 35 °C (closed cup method). Additional vapor-liquid equilibrium data include a vapor pressure of 3.5 kPa at 20 °C and an of 418 °C. These properties highlight nitromethane's behavior as a polar, volatile suitable for various applications, with its moderate influenced by its polarity.
PropertyValueConditionsSource
Molecular formulaCH₃NO₂-PubChem
Molecular weight61.04 g/mol-PubChem
AppearanceColorless, oily -OSHA
OdorDisagreeable-OSHA
Melting point-29.0 °C-PubChem
Boiling point101.2 °C760 mmHgPubChem
Density1.137 g/cm³20 °CPubChem
Viscosity0.65 cP20 °CSigma-Aldrich
Solubility in water12.5 g/100 mL20 °CASIS SDS
MiscibilityMiscible with , acetone-PubChem
Refractive index1.38120 °CPubChem
Flash point35 °CClosed cupPubChem
Vapor pressure3.5 kPa20 °CChemicalBook
Autoignition temperature418 °C-PubChem

Chemical properties

Nitromethane functions as a , attributable to the strongly electron-withdrawing nitro group that creates a significant molecular of 3.46 D. This arises from the uneven charge distribution, with the nitro group pulling away from the methyl moiety, enhancing its utility in dissolving polar substances without hydrogen bonding donation. The compound exhibits a high constant of 35.87 at 30 °C, which facilitates the and of ionic compounds by stabilizing charged species through electrostatic interactions. This property underscores its role in non-aqueous media where mobility is crucial, though its behavior is influenced by overall molecular affecting patterns. The alpha-hydrogen in nitromethane demonstrates notable acidity, with a value of 10.21, stemming from the stabilization of the conjugate —the nitromethyl anion—via delocalization into the nitro group. This acidity enables under mildly basic conditions, forming a -stabilized where the negative charge is distributed across the nitro oxygen atoms. Nitromethane remains stable under ambient conditions but displays sensitivity to strong bases or oxidizing agents, which can initiate through nucleophilic attack or processes on the nitro functionality. Characteristic features of the nitro group include a strong asymmetric stretch at 1560 cm⁻¹ and a symmetric stretch at 1380 cm⁻¹, reflecting the vibrational modes of the N=O bonds. In ¹H NMR , the methyl protons appear as a at 4.35 ppm, deshielded by the adjacent nitro group.

Synthesis and production

Laboratory

Nitromethane was first synthesized in by through the of sodium chloroacetate with , involving upon heating. This method remains a standard laboratory approach for small-scale preparation. In the procedure, (500 g, 5.3 mol) is dissolved in 500 g of cracked ice and neutralized with 40% solution (~360 mL) to form sodium chloroacetate, maintaining the below 20°C. A solution of (365 g, 5.3 mol) in 500 mL water is then added, and the mixture is heated in a 3-L flask equipped with a downward . Upon reaching 80°C, evolution begins, and the becomes exothermic, allowing spontaneous of nitromethane (b.p. 101°C) and water at 90–100°C. Additional heating to 110°C yields more product, and the aqueous distillates are salted out and redistilled. The combined nitromethane fractions are dried over and fractionally distilled under , collecting the fraction boiling at 98–101°C to give 115–125 g (35–38% yield based on ). Another common laboratory method is the Victor Meyer reaction, developed in 1872, which involves the of methyl with silver nitrite to selectively favor the over the nitrite ester. The reaction is represented by the equation: \ce{CH3I + AgNO2 -> CH3NO2 + AgI} Dry silver nitrite (44 g) is mixed with an equal volume of dry sand in a apparatus to facilitate and prevent caking. Methyl (41 g) is added gradually while heating gently; the mixture warms spontaneously, and nitromethane is distilled off as it forms. The distillate is dried over and purified by , yielding approximately 30 g of nitromethane (bp 100–102°C). This method typically provides yields of 50–70% under controlled dry conditions to minimize side reactions, such as formation of methyl nitrite. In both methods, post-synthesis purification involves drying with a like followed by under reduced pressure to separate nitromethane from water and impurities while avoiding .

Industrial production

Nitromethane is primarily produced on an industrial scale through the high-temperature vapor-phase of with at temperatures around 350–450 °C. This yields a mixture of nitroparaffins, including nitromethane (approximately 25% by weight), (approximately 10%), 1-nitropropane (approximately 25%), and 2-nitropropane (approximately 40%). The reaction is highly exothermic and proceeds via a free- , requiring precise control to optimize selectivity toward mononitration and avoid unwanted polynitro compounds or oxidation products. Unreacted propane and nitrating agents are typically recycled to improve efficiency. Catalysts such as metal oxides may be employed to enhance selectivity, though the core relies on radical initiation. Nitromethane is isolated from the product mixture via , leveraging its of 101 °C. An alternative route, described in patents, involves the gas-phase of using , , or a thereof as the nitrating agent at temperatures of 400–500 °C and pressures of 20–30 atm. The simplified reaction equation is: \ce{CH4 + HNO3 -> CH3NO2 + H2O} This method also follows a free-radical mechanism but is less commonly used commercially compared to the propane process. Major producers operate in the United States and . These manufacturing approaches emphasize and to manage the hazardous nature of nitro compounds and minimize waste.

Uses

Solvent applications

Nitromethane serves as a in various chemical processes, particularly for extractions where it facilitates the separation of polar s from non-polar mixtures. Its relatively low (approximately 10 g/100 mL at 20°C) combined with high enables efficient partitioning in biphasic systems, such as in processing where it dissolves and extracts specific resins or additives from hydrocarbon-based matrices. In , nitromethane acts as a reaction medium for organometallic reactions, leveraging its aprotic nature to stabilize carbanions and reactive intermediates without proton donation. This property makes it suitable for alkylations and certain nucleophilic additions, including applications in pharmaceutical synthesis where it supports reactions like those involving organolithium or other metal-mediated steps. Additionally, it functions as a cleaning solvent in the , effectively removing resins, adhesives, and flux residues from circuit boards and semiconductors due to its strong solvating power for polar materials like cyanoacrylates and acrylic coatings. Key advantages of nitromethane include its high solvency for inorganic salts and polar organics—exemplified by its ability to dissolve salts like —allowing it to outperform less polar solvents in specific extractions and dissolutions. However, its (boiling point 101°C, 28 mmHg at 20°C) can lead to losses during prolonged use, necessitating careful handling in open systems.

Fuel applications

Nitromethane serves as a high-performance in , particularly in and classes, where it is blended with in ratios up to 90% nitromethane and 10% as regulated by the (). This blend leverages nitromethane's inherent oxygen content, enabling it to act as a monopropellant that supports without relying solely on atmospheric air. The simplified reaction during is: $2 \ce{CH3NO2} \rightarrow 2 \ce{CO} + 3 \ce{H2} + \ce{N2} + \text{energy} This oxygen-rich property allows for richer fuel-air mixtures, enhancing power output in supercharged engines. In these applications, nitromethane boosts engine horsepower significantly compared to gasoline, with Top Fuel engines producing over 10,000 horsepower—far exceeding the 500-600 horsepower from comparably sized gasoline engines—due to the ability to inject larger fuel volumes per cycle. Although nitromethane has a lower specific energy content of approximately 11.3 MJ/kg versus gasoline's 44 MJ/kg, its volumetric energy delivery and cooling effect from high heat of vaporization enable higher mass flow rates and sustained high-rpm operation. For (RC) model engines in cars and planes, nitromethane is incorporated into two-stroke glow fuels at concentrations of 20-40%, mixed with as the primary component and 8-22% lubricating oil (such as or synthetic blends) to support and cooling. These blends increase and output, allowing higher RPMs and , though higher nitromethane percentages demand precise tuning to prevent overheating. Nitromethane also functions as a key in specialized liquid explosives, such as G, a mixture of and nitromethane that achieves a high of approximately 8,600 m/s, making it suitable for applications requiring rapid energy release. As of 2025, nitromethane's role in remains prominent, with the global market projected to grow at a (CAGR) of 4.1% through 2033, driven primarily by demand in high-performance fuels despite ongoing environmental regulations. Innovations in fuel supply, such as VP Racing Fuels' designation as the official NHRA provider, underscore its continued integration into competitive motorsports, including potential formulations for enhanced sustainability.

Other applications

In pesticide production, nitromethane acts as a precursor for nitromethyl-based insecticides, notably through Michael addition reactions in the synthesis of neonicotinoids like , a widely used crop protection agent. This role leverages nitromethane's reactivity to form nitro-substituted heterocycles essential for the insecticidal activity of these compounds. Nitromethane finds application in as a calibration standard for (NMR) , particularly for ¹⁵N and ¹⁴N chemical shifts, where it is recommended by IUPAC as a primary reference with a defined shift of 0 ppm in CDCl₃ solution. Its well-characterized spectrum facilitates accurate determination of nitrogen-containing compounds in . Emerging applications as of 2025 include the use of nitromethane in lithium metal battery electrolytes, where it contributes to surface modification of lithium anodes, enhancing stability and performance in ether-based systems like nitromethane-dimethoxyethane-lithium nitrate formulations. This additive improves ionic conductivity and suppresses dendrite formation, supporting advancements in high-energy-density rechargeable batteries.

Reactions

Acid-base properties

Nitromethane functions as a weak carbon via at the , described by the CH₃NO₂ ⇌ CH₂NO₂⁻ + H⁺, with a pKₐ of 10.21 measured in . This value reflects the enhanced acidity relative to alkanes (pKₐ ≈ 50), arising from the electron-withdrawing nitro group that facilitates removal of the α-proton. The conjugate base, the nitronate anion (CH₂NO₂⁻), gains stability through delocalization of the negative charge onto the nitro group's oxygen atoms, forming structures like ⁻O–N(=O)=CH₂ ↔ O₂N–CH₂⁻. This delocalization lowers the energy of the anion, contributing significantly to the observed acidity. As a base, nitromethane is extremely weak due to the electron-withdrawing nitro group, which diminishes its ability to accept a proton; occurs preferentially on an oxygen atom to yield the nitromethyl cation [CH₃–N(OH)=O]⁺, though this species is highly unstable and seldom isolated under standard conditions. equilibria with bases vary by strength: with NaOH in , the reaction is nearly complete (K ≈ 10⁵.⁵, derived from ΔpKₐ with H₂O), fully converting nitromethane to the nitronate. Nitromethane serves as an effective probe in acidity studies, particularly for assessing the basic strength of solid catalysts such as metal oxides, where is monitored via NMR or spectroscopy to quantify site basicity. Compared to (pKₐ = 8.6), nitromethane is less acidic, highlighting the stabilizing influence of the ethyl group's on the nitronate anion relative to the methyl substituent.

Organic reactions

Nitromethane serves as a nucleophilic in the Henry reaction, also known as the nitroaldol reaction, where it reacts with under basic to form β-nitro alcohols. The general transformation involves the of nitromethane to generate the nitronate anion, which adds to the of an aldehyde (RCHO), yielding RCH(OH)CH₂NO₂. This reaction is versatile for constructing carbon-carbon bonds and producing intermediates useful in pharmaceutical synthesis, with base catalysts such as or organic amines facilitating the process. The Henry reaction has been adapted for asymmetric synthesis using chiral catalysts, enabling the production of enantiopure β-nitro alcohols. Chiral complexes, such as those formed from bis(β-amino ) ligands and (OAc)₂·H₂O, promote the addition of nitromethane to substituted aldehydes with high enantioselectivity, achieving up to 95% under mild conditions in without additional base. Similarly, N,N'-dioxide/(I) complexes catalyze the reaction with aromatic and heteroaromatic aldehydes, delivering anti-β-nitro alcohols in yields up to 99% and enantioselectivities up to 97% , with diastereoselectivities exceeding 16:1. Primary nitroalkanes derived from nitromethane, such as those produced in the , undergo the to convert the nitro group to a carbonyl. The process involves acidification of the nitronate salt (RCH₂NO₂⁻) to form RCHO and HNO₂, typically using strong acids like under controlled conditions to avoid side reactions. This transformation is valuable for unmasking aldehydes from nitro precursors in multistep syntheses. Nitromethane can be reduced to (CH₃NH₂) through complete removal of the oxygen atoms from the nitro group. Common methods include catalytic using H₂ and , which proceeds under moderate pressure and temperature, or treatment with LiAlH₄ in , providing high yields of the primary . on the methyl group of nitromethane is limited due to the strong electron-withdrawing effect of the nitro group, which deactivates the alpha carbon toward electrophilic attack. Instead, nitromethane participates in reactions, such as those involving nitrosomethane intermediates formed via activation with iron catalysts and silanes, enabling additions to unsaturated systems for extensions. Recent developments highlight nitromethane's role in , particularly in sustainable synthesis of nitro compounds through electrochemical hydrogenolysis to , achieving selectivities over 50% with catalysts, and as a C1 in atom-efficient radical processes that minimize waste.

Safety and environmental aspects

Explosive and fire hazards

Nitromethane exhibits properties as a high , capable of under conditions of , intense , or . It is particularly sensitive to mechanical and can form shock-sensitive mixtures when contaminated with strong acids (such as hydrochloric, sulfuric, or ), bases, amines, or other incompatible materials like acetone or metal powders. decomposition may occur at temperatures exceeding 315°C, and sensitivity increases significantly under confinement, where it supports sustained . The pure compound has a of approximately 6300 m/s when confined, making it a for studying behavior. Despite its negative oxygen balance of -39.3%, nitromethane functions as a self-oxidizing material due to the oxygen supplied by the nitro group, enabling complete without external oxidizers in certain mixtures. This property contributes to its potential in air, with a lower limit of 7.3 vol% and an upper limit of 63 vol%, forming ignitable vapor-air mixtures over a wide range. Historical incidents underscore these risks; for instance, storage explosions in the 1980s were linked to that heightened , leading to unintended detonations in settings. To mitigate hazards, commercial formulations often include desensitizing additives, and nitromethane is subject to strict regulations, classified under UN 1261 as a Class 3 for transport. As a hazard, nitromethane is a Class IB with a closed-cup of 35°C and an of 417°C. It burns with a nearly colorless to pale yellow , producing potentially toxic fumes including oxides, and vapor-air mixtures can propagate back to the source due to vapors being heavier than air. Appropriate fire suppression involves dry chemical, , alcohol-resistant foam, or spray to cool containers and prevent explosive rupture, avoiding direct streams on burning liquid to minimize spread. Sensitivity testing, such as drop-hammer impact assessments, indicates nitromethane's relatively low mechanical sensitivity compared to primary like , though exact thresholds vary with purity and conditions.

Toxicity and environmental impact

Nitromethane exhibits moderate through multiple exposure routes. The oral (LD50) in rats is 1478 mg/kg body weight, indicating potential harm if swallowed in significant quantities. exposure leads to respiratory irritation and effects, with an LC50 >12.8 mg/L in rats over 1 hour. Direct contact causes skin irritation and serious eye damage, potentially leading to and conjunctival redness in animal models. Chronic exposure, particularly via , raises concerns for carcinogenicity, with nitromethane classified as possibly carcinogenic to humans (Group 2B) by the International Agency for Research on Cancer based on sufficient evidence of tumors in female rats. High-dose exposures can result in , including symptoms like , , and coordination impairment. In the environment, nitromethane behaves as a with rapid atmospheric degradation; its in air is approximately 4.3 hours due to direct photolysis, though indirect photolysis with hydroxyl radicals extends this to about 82 days. It exhibits low bioaccumulation potential, with a log Kow of -0.35 and bioconcentration factors in below 3, minimizing uptake in aquatic . Nitromethane is biodegradable in and through microbial action, with degradation rates supporting half-lives of 7.7 to 184 days in aquatic systems, though persistence may occur in soils. Its volatility contributes to air dispersion following releases, potentially affecting broader atmospheric compartments. Ecotoxicological studies demonstrate low to aquatic life, with an LC50 of 278 mg/L for fathead minnows over 96 hours, indicating minimal direct harm at environmentally relevant concentrations. However, spills pose a risk of contamination due to its and mobility in , potentially leading to long-term subsurface persistence if not remediated. Regulatory frameworks address these risks: the U.S. Environmental Protection Agency designates nitromethane as a hazardous substance under the Comprehensive Environmental Response, Compensation, and Liability Act (CERCLA), with a reportable quantity of 1000 pounds for releases. As of , ECHA is reviewing a proposal to classify nitromethane as a Category 2 under CLP, which may lead to future restrictions under REACH. Mitigation strategies emphasize protective measures during handling and response to incidents. , including chemical-resistant gloves, protective clothing, and respirators with organic vapor cartridges, is essential to prevent dermal, ocular, and . In case of spills, using inert absorbents like or is recommended, followed by proper disposal as , while preventing entry into waterways or drains to avoid ecological release.