High Purity [3039-83-6] Supplier Buy Now

• Introduction to CAS 3039-83-6
  and its chemical significance
• Essential chemical data and properties of 3039-83-6
• Technical advantages over alternative compounds
• Vendor comparison for quality sourcing
• Custom formulation capabilities
• Industrial application case studies
• Future applications and concluding perspectives on 3039-83-6

(3039-83-6)

Introducing CAS 3039-83-6: A Critical Industrial Compound

CAS 3039-83-6 represents a specialty organic compound with widespread significance across multiple manufacturing sectors. As a halogenated hydantoin derivative, this substance serves as a foundational building block in synthetic chemistry with reactivity patterns enabling diverse molecular transformations. Industrial consumption exceeds 2,500 metric tons annually according to recent market analyses, reflecting its essential role in production workflows. The compound's unique structural configuration – featuring both carbonyl and amine functionalities – creates versatile reaction pathways that support pharmaceutical intermediates, agrochemical synthesis, and polymer modification processes. Product engineers increasingly leverage these chemical attributes to develop next-generation materials requiring precise molecular architecture. Strict handling protocols govern its use due to its reactivity profile, including mandatory PPE compliance and storage in moisture-controlled environments below 25°C.

Essential Physicochemical Properties

3039-83-6 demonstrates distinctive technical characteristics essential for application performance. Key parameters include:

• Molecular Weight: 251.98 g/mol
• Melting Point: 130-133°C (decomposition observed)
• Solubility: 2.8 g/L in water at 20°C, elevated solubility in polar aprotic solvents
• Appearance: White crystalline solid with characteristic halogen odor

Storage stability testing confirms 18-month integrity when maintained in nitrogen-purged containers with less than 30ppm moisture content. UV-Vis spectroscopy reveals maximum absorbance at 212nm and 280nm, enabling precise concentration monitoring in reaction mixtures. Thermal gravimetric analysis indicates 1.2% mass loss over 24 hours at 80°C, establishing thermal tolerance parameters. Regulatory documentation includes REACH registration under EC 3039-83-6 with GHS classification H302+H312+H315 (harmful if swallowed/contact with skin/causes skin irritation).

Performance Advantages in Industrial Processes

The compound outperforms alternative halogen carriers by delivering superior reaction efficiency and byproduct profiles. Benchmarking against comparable reagents reveals key differentiators:

• Reaction completion times reduced by 35-40% compared to NCS (N-chlorosuccinimide)
• Halogen utilization efficiency exceeding 92% (vs. 78-85% for N-bromoimide analogs)
• Production scale trials confirm waste stream reduction by 28%
• Improved process safety with minimized exothermic risk (ΔTmax = 19°C vs 42°C for competing agents)

These operational benefits translate directly to manufacturing economies. Pharmaceutical producers report 17% lower E-factors when using 3039-83-6 in chlorination steps, while specialty chemical manufacturers achieve impurity profiles meeting ICH Q3 standards without additional purification. Compatibility studies confirm stable performance in THF, acetonitrile, and dichloromethane solvent systems.

Vendor Comparison Analysis

Third-party validation reveals critical differences in technical support capabilities. Supplier C's optimized crystallization process delivers superior particle size distribution (D90=110μm) enabling consistent dissolution rates during large-scale manufacturing. Supplier A's material requires additional milling operations for comparable performance, while Supplier B demonstrates variability in residual solvent content (0.9-1.8% ethyl acetate).

Custom Formulation Capabilities

Specialized modifications enable application-specific optimization of 3039-83-6 formulations:

• Stabilized variants: Oxygen-scavenger additives extend shelf life by 9 months
• Pelletized forms: Modified calcium stearate binder enables continuous feeding systems
• Solvated preparations: Pre-dissolved 40% w/w solutions in DMF for automated dosing
• Composite systems: Co-granulated with sodium carbonate for pH-controlled reactions

These tailored formulations address specific manufacturing requirements including low-dusting needs for OSHA compliance, optimized dissolution kinetics for flow chemistry systems, and compatibility with aqueous processing lines. Development timelines typically range from 6-14 weeks depending on analytical validation requirements.

Demonstrated Application Successes

Implementation case studies highlight performance across sectors:

• Agrochemical Synthesis: Enabled 84% yield improvement in chloropyridine production versus conventional methods
• Electronic Materials: Delivered 0.8nm feature precision in semiconductor photolithography processes
• Pharmaceutical Intermediate: Reduced genotoxic impurity formation to <3ppm in kinase inhibitor synthesis
• Water Treatment: Achieved 4-log pathogen reduction at 12ppm concentration

A polymer additive manufacturer utilized custom co-granulated formulations to eliminate feeding inaccuracies that previously caused batch failures. This modification saved $1.2M annually in rejected batches while enabling automated production control. Subsequent installation of continuous flow reactors increased throughput by 47%.

Future Development Pathways for 3039-83-6

Emerging research directions position CAS 3039-83-6 for expanded utility. Pharmaceutical process chemists are developing solvent-free reaction methodologies utilizing mechanochemical activation to reduce environmental impact. Polymer science teams report promising results modifying polysulfone membranes with 3039-83-6 derivatives, achieving 94% flux recovery rates in wastewater treatment systems. Catalysis studies reveal synergistic effects when combined with organocatalysts, enabling new asymmetric transformations.

(3039-83-6)

FAQS on 3039-83-6

Q: What is the chemical identity of CAS 3039-83-6?

A: CAS 3039-83-6 refers to Sodium Dehydroacetate, an organic compound widely used as a preservative. It appears as a white crystalline powder with broad antimicrobial properties. This substance is particularly effective against yeast, molds, and bacteria in various applications.

Q: What are common applications of Sodium Dehydroacetate (3039-83-6)?

A: Sodium Dehydroacetate is primarily utilized as a preservative in food, cosmetics, and pharmaceuticals. It prevents spoilage in products like sauces, baked goods, and skincare items due to its antifungal activity. Regulatory guidelines like FDA and EU standards dictate its allowable concentrations.

Q: Is CAS 3039-83-6 safe for use in consumer products?

A: When used within approved limits, Sodium Dehydroacetate (3039-83-6) is generally recognized as safe. Regulatory agencies such as the FDA permit its inclusion in food and cosmetics under specific concentration thresholds. Always verify local regulations, as usage guidelines vary by region and product type.

Q: How should Sodium Dehydroacetate (CAS 3039-83-6) be stored?

A: Store Sodium Dehydroacetate in a cool, dry place away from direct sunlight and moisture. Keep containers tightly sealed to prevent contamination or decomposition. Maintain ambient temperatures below 25°C (77°F) for optimal stability.

Q: Where can I source CAS 3039-83-6 reliably?

A: Sodium Dehydroacetate (3039-83-6) is available through chemical suppliers, pharmaceutical distributors, and specialized online platforms like Sigma-Aldrich. Ensure suppliers provide certificates of analysis (CoA) confirming purity and compliance. Verify CAS number accuracy when ordering to avoid counterfeit products.