High-Purity Cuprous Iodide (CAS No.) Trusted Suppliers & Applications

• Introduction to Cuprous Iodide and Its Industrial Relevance
• Technical Advantages of High-Purity Cuprous Iodide
• Comparative Analysis of Leading Cuprous Iodide Suppliers
• Customized Solutions for Diverse Industrial Applications
• Case Studies: Cuprous Iodide in Advanced Manufacturing
• Quality Standards and Compliance in Production
• Future Trends in Cuprous Iodide Supply and Demand

(cuprous iodide cas no)

Understanding Cuprous Iodide CAS No and Its Industrial Significance

Cuprous iodide (CuI), identified by CAS No 7681-65-4, is a critical inorganic compound widely utilized in electronics, catalysis, and optical applications. With a global market valued at $148 million in 2023, demand is projected to grow at a CAGR of 6.2% through 2030, driven by its role in photovoltaic cells and OLED displays. This halogenated copper compound exhibits exceptional conductivity and thermal stability, making it indispensable for high-tech industries.

Technical Advantages of High-Purity Cuprous Iodide

Manufacturers prioritize ≥99.99% purity grades to meet stringent industry requirements. Key performance metrics include:

• Thermal stability up to 600°C
• Electrical resistivity of 1.2×10⁻³ Ω·cm
• Particle size consistency (D50: 2–5 μm)

Advanced synthesis methods like solvothermal processing reduce impurities to <50 ppm, ensuring reliability in semiconductor fabrication.

Supplier Comparison: Key Market Players

Supplier	Purity (%)	Lead Time (Days)	Price ($/kg)	Certifications
Supplier A	99.995	14	420	ISO 9001, REACH
Supplier B	99.99	21	380	UL, RoHS
Supplier C	99.95	10	310	ISO 14001

Tailored Solutions for Industry-Specific Needs

Customization options address unique application requirements:

• Electronics: Submicron particles (0.5–1.2 μm) for thin-film deposition
• Photonics: Controlled crystallinity (XRD FWHM <0.15°)
• Catalysis: Surface area optimization (15–25 m²/g)

Application Success Stories

A leading OLED manufacturer achieved 18% efficiency improvement using Supplier A’s CuI in hole-transport layers. In photovoltaic applications, nano-structured CuI increased cell durability by 40% under accelerated aging tests.

Compliance and Quality Assurance Protocols

Top suppliers maintain:

• Batch-to-batch variance <0.8%
• Heavy metal content <5 ppm
• 24-month shelf-life guarantees

Strategic Outlook for Cuprous Iodide CAS 7681-65-4

With 73% of current demand originating from Asia-Pacific electronics hubs, suppliers are investing in regional distribution centers to reduce logistics costs by 12–15%. Emerging applications in quantum dot synthesis (forecasted 29% CAGR) will further drive innovation in cuprous iodide formulations.

(cuprous iodide cas no)

FAQS on cuprous iodide cas no

Q: What is the CAS number for cuprous iodide?

A: The CAS number for cuprous iodide is 7681-65-4. This unique identifier is used for precise chemical classification and regulatory compliance. Always verify this number with suppliers for accuracy.

Q: What are the primary uses of cuprous iodide?

A: Cuprous iodide is widely used as a catalyst in organic synthesis, particularly in coupling reactions. It also serves in cloud seeding and photovoltaic applications. Its properties make it valuable in specialized industrial processes.

Q: How can I identify reliable cuprous iodide suppliers?

A: Reliable suppliers often provide certified documentation, including CAS number (7681-65-4) and purity grades. Check for compliance with industry standards like ISO and reviews from other clients. Reputable chemical distributors or B2B platforms are recommended sources.

Q: Is cuprous iodide hazardous to handle?

A: Cuprous iodide may pose risks if inhaled or ingested, requiring proper PPE like gloves and masks. Always follow SDS (Safety Data Sheet) guidelines provided by suppliers. Store it in a cool, dry environment away from incompatible substances.

Q: What factors influence cuprous iodide pricing?

A: Pricing depends on purity levels, order volume, and supplier location. Specialty grades for research or electronics often cost more than industrial-grade material. Market demand and raw material availability also affect fluctuations.