For professionals in the chemical and pharmaceutical industries, understanding chemical specifications is not just a technical detail; it's a critical aspect of procurement that ensures product quality, safety, and process efficiency. When you decide to buy a chemical intermediate, such as (S)-2-[(4-Chlorophenyl)(4-piperidinyloxy)methyl]pyridine (CAS: 201594-84-5), the associated specifications are your roadmap to verifying its suitability for your intended application. This guide breaks down the essential components of chemical specifications and why they matter.

What are Chemical Specifications?

Chemical specifications are a set of parameters that define the quality, purity, and characteristics of a chemical substance. They are typically presented in a document called a Certificate of Analysis (CoA) or a Product Specification Sheet, provided by the manufacturer or supplier. These specifications serve as a contract between the buyer and seller, ensuring that the product delivered meets agreed-upon standards.

Key Parameters in Chemical Specifications:

1. Product Identification:

This is the most basic information, ensuring you have the correct chemical. It includes:

  • Chemical Name: The systematic name (e.g., (S)-2-[(4-Chlorophenyl)(4-piperidinyloxy)methyl]pyridine).
  • CAS Number: A unique numerical identifier (e.g., 201594-84-5). Crucial for unambiguous identification.
  • Synonyms: Alternative names the chemical might be known by.
  • Molecular Formula and Weight: (e.g., C17H19ClN2O, 302.799 g/mol). Helps in stoichiometric calculations.

2. Purity (Assay):

This is often the most critical specification. It indicates the percentage of the desired compound present in the sample. For pharmaceutical intermediates, high purity is paramount.

  • Example: An assay of '≥98.0%' for (S)-2-[(4-Chlorophenyl)(4-piperidinyloxy)methyl]pyridine means that at least 98.0% of the material is the specified compound.
  • Why it Matters: Higher assay generally means fewer impurities, which can interfere with downstream reactions, affect API efficacy, or introduce toxicity.

3. Impurity Profile:

While high assay is important, knowing the nature and levels of impurities is equally crucial, especially for pharmaceutical applications. Specifications may list:

  • Specific Impurities: Known by-products or related substances.
  • Total Impurities: The sum of all known and unknown impurities.
  • Limits: Maximum allowable percentages for each impurity or total impurities.
  • Why it Matters: Impurities can be reactive, toxic, or affect the physical properties of your final product.

4. Physical and Chemical Properties:

These describe the substance's appearance and behavior.

  • Appearance: Color and physical state (e.g., 'Dark yellow to brown oily liquid'). This is a quick visual check.
  • Melting Point/Boiling Point: Indicates the substance's thermal properties.
  • Density: Useful for volume-to-mass conversions.
  • Solubility: Important for formulation and reaction planning.
  • Index of Refraction: A physical characteristic.
  • Flash Point: Relevant for safety during handling and storage.

5. Specific Optical Properties (for Chiral Compounds):

For chiral intermediates like (S)-2-[(4-Chlorophenyl)(4-piperidinyloxy)methyl]pyridine, enantiomeric purity is a key specification.

  • Optical Rotation: The degree to which a chiral compound rotates plane-polarized light.
  • Enantiomeric Excess (ee): The percentage difference between the two enantiomers. High ee (e.g., >98%) is vital for stereoselective synthesis.

6. Storage and Handling Recommendations:

Specifications often include recommended storage conditions (e.g., 'Store in a cool, ventilated place') and safety precautions, which are crucial for maintaining product integrity and ensuring safe operations.

Why Adhere to Specifications?

When you buy from a reputable manufacturer and supplier, their specifications are a guarantee of quality. Adhering to these specifications is vital:

  • Process Reliability: Consistent quality ensures predictable reaction outcomes and batch-to-batch consistency.
  • Product Quality: Directly impacts the purity, safety, and efficacy of your final API or product.
  • Regulatory Compliance: Meeting stringent purity requirements is essential for regulatory approval.
  • Cost Efficiency: Avoiding costly batch failures or rework due to substandard materials.

In essence, chemical specifications are the language of quality in the chemical industry. They empower buyers to make informed decisions, ensure they are purchasing the correct materials, and ultimately contribute to the success of their research, development, and manufacturing endeavors. Always review the CoA thoroughly before purchase and discuss any ambiguities with the supplier.