For scientists and chemical engineers, a deep understanding of a compound's chemical profile is fundamental to its effective utilization. 6-Hydroxy-1-indanone (CAS: 62803-47-8) is a molecule of significant interest due to its structure and reactivity, making it a valuable intermediate in various synthetic pathways. This article explores its key properties and the common synthetic methodologies employed by manufacturers.

Physical and Chemical Properties

6-Hydroxy-1-indanone is characterized by its distinct physical attributes:

  • Appearance: It presents as a yellow powder.
  • Purity: Typically offered at 97% purity, suitable for most advanced synthetic applications.
  • Melting Point: The compound melts in the range of 154-158 °C, indicating a stable solid form at room temperature.
  • Solubility: It exhibits good solubility in methanol, a common solvent in organic synthesis, facilitating its incorporation into various reaction mixtures.
  • Molecular Formula and Weight: C₉H₈O₂ (148.16 g/mol).

Spectroscopic Characterization

While detailed spectroscopic data is beyond the scope of a brief overview, standard analytical techniques used by suppliers to confirm its identity and purity include:

  • NMR Spectroscopy (¹H and ¹³C): Provides detailed information about the molecule's carbon-hydrogen framework, confirming the presence of aromatic rings, the carbonyl group, and the hydroxyl group.
  • Mass Spectrometry (MS): Confirms the molecular weight and can help identify fragmentation patterns indicative of its structure.
  • IR Spectroscopy: Shows characteristic absorption bands for the O-H stretching of the hydroxyl group and the C=O stretching of the ketone.

Synthetic Routes Employed by Manufacturers

The synthesis of 6-Hydroxy-1-indanone typically relies on established organic chemistry principles. Common routes include:

1. Friedel-Crafts Acylation/Alkylation followed by Hydroxylation: This classical approach often involves building the indanone ring system from aromatic precursors and then introducing the hydroxyl group at the 6-position. These reactions may utilize Lewis acid catalysts and require careful control of reaction conditions to maximize yield and purity.

2. Functionalization of Existing Indanone Structures: Alternatively, manufacturers might start with a pre-formed indanone scaffold and introduce the hydroxyl group through targeted chemical reactions. Protecting group strategies might be employed if other reactive sites on the molecule need to be masked during the synthesis.

3. Specific Intermediates for Complex Synthesis: As noted, this compound is often synthesized as an intermediate for more complex molecules. Manufacturers specializing in pharmaceutical intermediates are adept at producing it to meet stringent quality standards required for drug development. When you need to buy this compound, inquiring about the synthetic route used can provide further assurance of its quality and provenance.

For procurement specialists seeking reliable sources, understanding these aspects of 6-Hydroxy-1-indanone is crucial. Partnering with manufacturers who can provide high-purity material, detailed analytical data, and competitive prices ensures that your research and production processes are supported by quality chemical intermediates. Always request a quote and consider available packages for your specific needs.