For scientists and researchers immersed in chemical synthesis, a deep understanding of the properties and production methods of key intermediates is fundamental to innovation. 4-(Methylsulfonyl)-2-nitrobenzoic Acid (CAS 110964-79-9) is one such compound, a valuable building block whose utility stems from its precise chemical characteristics and accessible synthesis routes. This article provides an overview of its key properties and common synthesis approaches, offering valuable insights for R&D professionals looking to incorporate it into their work, and for buyers seeking to understand the manufacturing process from potential suppliers.

Key Chemical Properties and Characteristics

4-(Methylsulfonyl)-2-nitrobenzoic Acid is recognized for its distinct chemical profile:

  • Appearance: Typically a pale yellow solid. This visual cue is often the first indicator of product quality.
  • Purity: High purity, generally above 98%, is crucial for its application in sensitive synthesis, particularly for pharmaceutical intermediates.
  • Solubility: It exhibits solubility in polar organic solvents such as DMSO and methanol, and slight solubility in water, which influences its handling and reaction conditions.
  • Melting Point: A melting point typically in the range of 211-212°C indicates its crystalline structure and stability.
  • Molecular Structure: The presence of a carboxylic acid group (-COOH), a nitro group (-NO2), and a methylsulfonyl group (-SO2CH3) on a benzene ring provides multiple reactive sites for chemical transformations.

Synthesis Routes: From Precursors to Product

The synthesis of 4-(Methylsulfonyl)-2-nitrobenzoic Acid often involves nitration and oxidation steps. A common pathway described in literature and patents involves starting from a precursor like 2-nitro-4-methylsulfonyltoluene. The process typically entails oxidizing the methyl group to a carboxylic acid while maintaining the nitro and methylsulfonyl functionalities.

One detailed synthesis method involves:

  • Reacting 2-nitro-4-methylsulfonyltoluene with nitric acid under controlled high temperatures, often in the presence of sulfuric acid and a catalyst like vanadium pentoxide.
  • Careful control of reagent addition rates, temperature, and reaction time is essential to maximize yield and purity while managing exothermic reactions and byproducts like nitrogen oxides.
  • Post-reaction, the product is isolated through filtration, washing, and drying. Recovery and potential reuse of reagents, such as nitric acid, are also considerations in industrial-scale production for cost efficiency.

Other synthetic strategies might involve different starting materials or catalytic systems, but the core challenge remains selectively introducing the required functional groups with high fidelity.

Implications for Buyers and Manufacturers

For R&D scientists, understanding these synthesis routes can help in troubleshooting reaction issues or exploring alternative pathways. For procurement managers, knowledge of the manufacturing process from potential suppliers provides a basis for evaluating their technical capabilities and quality control measures. When you are looking to buy 4-(Methylsulfonyl)-2-nitrobenzoic Acid, asking potential manufacturers about their synthesis process, quality control, and their ability to produce at scale can help in selecting a reliable partner. Manufacturers in China, leveraging their extensive chemical synthesis expertise and infrastructure, are well-positioned to supply this intermediate consistently and cost-effectively. Engaging with these suppliers means understanding not just the price, but the underlying science and quality commitment.