Overview:
Ethanone, 1-[4-[1-[4-(acetyloxy)phenyl]-1-methylethyl]phenyl]-,this compound, identified by CAS Number 1256572-99-2, is a specialized organic intermediate utilized primarily within the electronic chemicals sector. It serves as a critical building block in the synthesis of advanced polymers and photoactive compounds (PACs) required for high-resolution photolithography.
Chemical Identity and Properties
- IUPAC Name: 1-[4-[2-[4-(acetyloxy)phenyl]propan-2-yl]phenyl]ethanone
- Molecular Formula: C19H20O3
- Molecular Weight: Approximately 296.36 g/mol
- Structural Characteristics: The molecule features a central isopropylidene bridge (bisphenol A derivative structure) connecting two phenyl rings. One ring is substituted with an acetyl group (ethanone moiety), while the other contains an acetoxy group (ester).
The presence of the acetoxy group (CH3COO−) is particularly significant in industrial applications, as it can act as a protecting group or a site for further chemical modification, such as deacetylation to reveal a reactive phenolic hydroxyl group.
Industrial Role in Semiconductor Manufacturing
The primary application of this compound is as a precursor for materials used in Photoresist Industry. Photoresists are light-sensitive coatings used in the semiconductor industry to transfer intricate circuit patterns onto silicon wafers.
- Monomer for Specialty Polymers
This compound is often used to synthesize polymers with high thermal stability and specific solubility profiles. The bisphenol-like backbone provides structural rigidity, which is essential for maintaining the "critical dimension" (CD) control during the baking and etching phases of chip fabrication.
- Functionalization for Chemically Amplified Resists (CARs)
In modern Deep Ultraviolet (DUV) and Extreme Ultraviolet (EUV) lithography, the compound aids in the creation of polymers that exhibit high sensitivity to radiation. The acetyl and acetoxy functionalities allow chemists to fine-tune the dissolution rate of the resist in alkaline developers.
Applications in Electronic Chemicals
Beyond primary lithography, the compound and its derivatives find utility in:
- Dielectric Materials: Used in the formulation of interlayer dielectrics where low-dielectric constants and high purity are mandatory.
- Electronic Packaging: Enhancing the adhesive and thermal properties of resins used in microelectronic encapsulation.
- Advanced Coatings: Providing chemical resistance and mechanical durability in high-tech displays and optical components.
Handling and Regulatory Standards
As a high-purity electronic chemical, the following standards typically apply during industrial use:
| Aspect | Requirement |
| Purity Levels | Often requires ≥98% or 99% purity, with metallic impurities restricted to parts-per-billion (ppb) levels. |
| Storage | Should be stored in a cool, dry, and well-ventilated area, away from strong oxidizing agents. |
| Safety | Handling requires standard laboratory PPE (gloves, goggles, lab coat). Users should consult the specific Safety Data Sheet (SDS) for toxicity and environmental impact data. |
Conclusion
The compound CAS 1256572-99-2 is an indispensable component in the supply chain for next-generation electronics. By enabling the synthesis of high-performance photoresist materials, it directly contributes to the ongoing miniaturization and efficiency of semiconductor devices.
Product:1256572-99-2, Semiconductor Photoresist, Electronic Chemicals
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