For professionals in the chemical industry, a deep understanding of the fundamental properties and synthesis routes of key intermediates like o-tolunitrile (CAS 529-19-1) is crucial for informed sourcing and application. This aromatic nitrile, often referred to as 2-methylbenzonitrile, plays a vital role in numerous downstream chemical processes, making its chemical profile a subject of interest for procurement specialists and research scientists alike.

Unpacking the Chemical Nature of o-Tolunitrile

o-Tolunitrile is classified as an aromatic nitrile, possessing a molecular formula of C8H7N. Its structure is characterized by a nitrile group (-C≡N) attached to the ortho position of a toluene (methylbenzene) ring. This structural arrangement imparts specific chemical and physical properties:

  • Appearance: Typically observed as a clear, colorless to slightly yellow liquid.
  • Molecular Weight: Approximately 117.15 g/mol.
  • Boiling Point: Around 205 °C, indicating its stability at moderate to high temperatures.
  • Melting Point: Approximately -13 °C, confirming its liquid state under standard conditions.
  • Solubility: Moderately soluble in water, but highly soluble in common organic solvents like ethanol, ether, and acetone, which is advantageous for its use in various reaction media.

The nitrile group is highly polar, contributing to o-tolunitrile's utility as a solvent and a reactive moiety in synthesis. Its relatively high boiling point and stability make it suitable for reactions that require elevated temperatures.

Industrial Synthesis of o-Tolunitrile

The most common and industrially significant method for producing o-tolunitrile involves a series of well-established chemical transformations starting from toluene:

  1. Nitration of Toluene: The process begins with the electrophilic aromatic substitution of toluene using a nitrating mixture (typically concentrated nitric and sulfuric acids). Due to the activating and ortho/para-directing nature of the methyl group on toluene, this reaction primarily yields a mixture of nitrotoluene isomers, with ortho-nitrotoluene being a significant product.
  2. Conversion to Nitrile: The ortho-nitrotoluene is then subjected to a process that converts the nitro group (-NO₂) into a nitrile group (-CN). Common industrial methods for this transformation include catalytic hydrogenation or reaction with specific dehydrating agents and ammonia (ammoxidation), although direct conversion from the nitro group is often achieved through reduction to an amine followed by cyanation, or via intermediates. A more direct conceptual route often described involves processes that replace the nitro group with a nitrile function, or reduction of the nitro group followed by conversion. However, the most efficient industrial routes often focus on direct ammoxidation of toluene derivatives or related pathways that yield the nitrile group efficiently.

The efficiency and scalability of these synthesis routes are critical for manufacturers aiming to supply o-tolunitrile at competitive prices. Understanding these processes helps buyers appreciate the quality and consistency of the product they can expect from reputable suppliers.

Why Sourcing Matters

For businesses looking to buy o-tolunitrile, partnering with a manufacturer that masters these synthesis techniques is key. A manufacturer with robust process control ensures high purity, consistent yields, and a reliable supply. As a prominent supplier of o-tolunitrile from China, we pride ourselves on our advanced manufacturing capabilities and our commitment to quality, making us an ideal partner for your chemical sourcing needs.

By understanding the chemistry behind o-tolunitrile, from its inherent properties to its synthesis, industry professionals can make more informed decisions when procuring this essential chemical intermediate, ensuring the success of their own product development and manufacturing cycles.