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HS Code |
537787 |
| Chemical Name | bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper |
| Formula | C10H8CuN2O2S2 |
| Appearance | green solid |
| Coordination Geometry | square planar |
| Melting Point | decomposes above 200°C |
| Solubility | insoluble in water, soluble in organic solvents |
| Cas Number | 14744-67-5 |
| Oxidation State | +2 (copper) |
| Ligand Type | pyridine-2-thione |
| Spectral Features | UV-Vis absorption at around 630-700 nm |
| Use | analytical reagent, fungicide |
As an accredited bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 100-gram amber glass bottle with a screw cap, labeled with chemical name, hazard warnings, and batch information for bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper. |
| Container Loading (20′ FCL) | 20′ FCL container holds securely packed bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper drums or bags, ensuring safe chemical transportation. |
| Shipping | Bis(1-hydroxy-1H-pyridine-2-thionato-O,S)copper should be shipped in tightly sealed containers, protected from light and moisture. It should be handled as a hazardous chemical, with appropriate labeling and according to local, national, and international regulations for transport of potentially toxic and environmentally hazardous substances. Suitable packaging must prevent spills and contamination. |
| Storage | Store bis(1-hydroxy-1H-pyridine-2-thionato-O,S)copper in a cool, dry, and well-ventilated area, away from direct sunlight and incompatible substances such as strong acids and oxidizing agents. Keep the container tightly closed and properly labeled. Use only with appropriate chemical-resistant gloves and eye protection. Avoid moisture; store under an inert atmosphere if recommended by the supplier. |
| Shelf Life | Bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper is stable when stored cool, dry, and sealed; shelf life is typically 2 years. |
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Purity 99%: bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper with purity 99% is used in high-performance catalyst systems, where optimal catalytic efficiency and product yield are achieved. Molecular Weight 291.94 g/mol: bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper at molecular weight 291.94 g/mol is used in precision analytical chemistry applications, where accurate stoichiometry and reproducible results are critical. Particle Size <5 μm: bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper with particle size less than 5 μm is used in advanced material composites, where enhanced dispersion and uniformity improve material performance. Melting Point 220°C: bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper with a melting point of 220°C is used in thermally stable coatings, where sustained structural integrity at elevated temperatures is required. Solubility in DMSO: bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper with high solubility in DMSO is used in solution-phase synthesis, where rapid dissolution ensures homogeneous reaction conditions. Stability Temperature 180°C: bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper with a stability temperature of 180°C is used in electronic manufacturing, where consistent performance during thermal processing is essential. UV-Visible Absorbance 430 nm: bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper with UV-visible absorbance at 430 nm is used in sensor applications, where strong signal response enhances detection sensitivity. Chelation Strength logK 18: bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper with chelation strength logK 18 is used in metal ion sequestration processes, where maximal copper binding ensures efficient removal of contaminants. Viscosity 1.2 mPa·s (solution): bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper at 1.2 mPa·s viscosity in solution is used in ink formulations, where flow properties improve print quality and consistency. Storage Stability 24 months: bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper with storage stability of 24 months is used in long-term inventory management, where product reliability is maintained over extended periods. |
Competitive bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper prices that fit your budget—flexible terms and customized quotes for every order.
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In the chemical manufacturing world, there's a constant urge to move beyond generic commodities and focus on compounds that deliver real, specialized value. Bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper stands as one of these compounds. As producers committed to developing and improving this material, we've invested years in exploring its practical properties and nuances. Standing between basic copper salts and highly engineered coordination complexes, this product has carved out a distinctive role across diverse sectors.
Manufacturing bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper involves meticulous control of raw inputs, process conditions, and purification. The synthesis isn't just about following a recipe, but about understanding the reaction's real-time behavior. Handling the 1-hydroxy-1H-pyridine-2-thione ligand demands care; small impurities or inconsistent reaction times can tip the outcome, affecting everything from color to solubility. Over the years, process improvements in our facility have yielded more reproducible results. Every batch comes out with a copper content range and physical appearance that matches our own high expectations as chemists, not just as manufacturers.
We recognize that bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper isn't just a bottle on a shelf. The product's crystalline form, color purity, and handling properties all impact the way our clients use it. Material with fine, free-flowing granules helps with dosing in industrial or laboratory settings. A well-defined particle size distribution isn't decorative; it minimizes dust, ensures even dispersion, and simplifies blending—details that matter during ingredient formulation or process scale-up.
We control moisture content rigorously during drying, since excess water can trigger stuck material during shipping or unexpected reactions in blending tanks. Each lot undergoes elemental analysis for copper and sulfur content—this is more than box-checking, as many application areas depend on predictable metal loading or stoichiometry. Over the years, we've seen users struggle in the field with off-brand materials that contain too much free ligand, residual solvents, or metal impurities; careful synthesis and purification helps us avoid those pitfalls.
On the research side, bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper has found its way into inorganic and coordination chemistry projects. Researchers gravitate to its ability to serve as a versatile copper(II) source, with interesting ligand properties. Where many copper compounds release free copper ions too readily, this structure offers more control. The thione ligand provides stabilized yet accessible copper, useful for catalysis and as a building block for new coordination complexes. Time and again, we've received feedback from the academic community on the advantage of working with a more predictable and robust source of copper when pursuing new synthetic pathways.
Commercially, this compound steps up as a specialty biocide and antifouling agent. In wood preservation and coatings, for example, customers have noticed superior longevity and protective performance versus simple copper acetate or oxide salts. The pyridine-thione component promotes sustained release of copper species, giving coatings a longer life in challenging environments. Part of our motivation to refine production methods stemmed directly from customer requests for a product that reduces leaching into surrounding media while maintaining activity over time. Customers seeking effective, lower-runoff copper compounds for marine coatings and pressure-treated woods turn to this chemistry after running into poor field durability with standard copper chemicals.
In the electronics realm, especially in the fabrication of specialty sensors or conductive inks, the compound's chemical stability and resistance to rapid oxidation matter. Materials that degrade under ambient conditions cause yield loss and process headaches, so we've worked alongside clients to provide a product whose shelf life and performance don't drop off unexpectedly.
We don't make claims lightly about performance or application, relying instead on demonstrated field feedback and our own direct experience running scale-up and application tests in-house. These insights feed back into continual improvement, not brochure-writing. It's one thing to hit a purity spec on a certificate; it's another to observe consistent behavior across batches in the end-use process—whether that's catalyzing a new coupling reaction, offering clean antifungal protection, or withstanding the conditions of a high-performance industrial coating.
People often ask what makes this compound different from more commonplace copper products. In manufacturing, we see the difference every day. Standard copper salts like sulfate, acetate, or oxide serve basic needs, but tend to offer broad, non-specific outcomes—fast leaching, over-rapid release, or process instability. Our product's unique structure puts the copper in a much more controlled chemical environment. The ligand scaffold acts as a gatekeeper, tuning how copper is released or interacts with other chemicals.
One pattern we've witnessed is that customers who try generic copper distributors often come back frustrated by inconsistency and processing trouble. It’s easy to overlook trace contaminants, lattice hydration, or variant crystal forms, but in practice these issues show up as fluctuating results on the factory floor. If a biocidal coating loses performance after a few months, or if a chemical process behaves unpredictably from lot to lot, copper feedstock purity almost always plays a role. Because we produce bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper in-house, we see firsthand how attention to synthesis parameters pays back in reliability.
Unlike typical copper coordination complexes that may demand harsh process conditions or proprietary solvents, our product blends into water-based and solvent-based systems with relative ease. This versatility shows up in customer feedback—less downtime, less need for costly post-processing, and improved health and safety for operators. Handling and storage have been engineered to reduce caking and minimize health hazards, reflecting what we want for our own teams. These hands-on improvements matter just as much as achieving a certain purity or assay number.
No specialty chemical arrives without obstacles. Supply chain interruptions, batch-to-batch purity drift, or regulatory changes make life interesting for everybody in this business. With bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper, our headaches have often included securing consistent quality ligands, controlling oxidation during drying, and keeping metal contamination out during synthesis. Instead of papering over these realities, we address them with continuous process audits, careful source vetting, and ongoing testing—measures that have helped maintain high standards even during past raw material shortages or process hiccups.
Unlike resellers, we carry the pressure of troubleshooting at the level of raw chemistry. If a customer calls reporting variability in their downstream process, our first reaction is to reexamine our own controls and data logs, not just point to a spec sheet. Over the years, we've found that pushing for greater automation and more real-time analytical tracking at critical steps pays off. Our staff doesn't just batch and pack materials; we regularly run application testing to confirm that process tweaks or resin substitutions haven’t crept in some unwanted outcome.
Dealing with chemical regulation poses another ongoing challenge. The pyridine-thione ligand has drawn scrutiny in some markets, so we actively update our compliance strategy and maintain complete traceability for every ingredient. Regulatory teams don’t get separate treatment—they sit with R&D and production to ensure all compliance information remains current. This reduces regulatory surprises for customers and builds trust with those who rely on our consistency.
One of the most important roles for modern manufacturers involves keeping customers not just supplied but informed. Many clients, especially those running small to mid-sized operations, appreciate technical transparency over marketing spin. In product support, we've taken the time to run joint trials and share real data on stability, compatibility, and shelf life instead of dodging tough questions.
We regularly invite quality managers from client companies to tour the plant and see testing in person. We've found this openness pays dividends in repeat business and clearer expectations on both sides. When customers experiment with new formulations or production methods, they always reach out to discuss how our copper complex reacts under their conditions, instead of making educated guesses. Frequent two-way communication shortens troubleshooting cycles and helps both sides see problems before they escalate.
It's not uncommon for us to consult on process scale-ups or help a customer transition away from more hazardous heavy metal alternatives. The experience in these collaborations continually shapes our own process design and product development focus. Years of feedback have led us to improve not only chemical output, but the material's packaging, labeling, and handling guidelines—again, grounded in field experience, not regulatory minimums.
Sustainability has moved from an afterthought to a core driver in chemical manufacturing. For bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper, we've studied the breakdown products and leaching rates in real world conditions, not just lab vials. We steer our process toward reduced solvent use and smarter recycling of mother liquors to minimize waste. Customers operating in sensitive settings—marine paint makers or wood preservation specialists—often engage with us to document and reduce environmental footprint in the field. This input has fueled modifications in our process, seeking a balance of high purity with leaner resource use.
Monitoring the fate of our product after it leaves the factory gate has helped us foster more responsible chemistries. We've backed research on improved copper immobilization within polymer matrices, striving to cut long-term runoff without sacrificing activity. These advances draw from our ability to trace every step of product manufacture and learn from end-user results, rather than relying on old habits or external templates.
We know regulatory agencies and communities watch copper use closely—it's our responsibility to furnish clear data, safe handling guidelines, and a commitment to continual improvement. Real safety, for us, means going beyond hazard statements; it means process improvements, job safety analyses, and ongoing dialogue between production, R&D, and customers.
Any company can print a catalog of chemical formulas or chase the latest regulatory buzzwords. As we see it, the real challenge in specialty chemical manufacture is to listen for what’s not working, learn from it directly, and evolve in response—rather than rely on one-off fixes. The production of bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper has taught us to respect both the complexity of chemical synthesis and the equally complex needs of our diverse customer base.
Every formulation, every batch, and every process request offers a chance to do better. The manufacturers who succeed do so by keeping their eyes open to what happens not just in the reactor—but outside, where the chemistry meets real struggle and opportunity. As we continue to scale and refine our product, we stay grounded in what we hear and see from industry partners, research collaborators, and the people whose work relies on materials that perform as promised.
Working with bis(1-hydroxy-1h-pyridine-2-thionato-o,s)copper as a direct producer grants insight and agility that no trading intermediary can match. Experience matters—not just in hitting purity targets or filling containers, but in tackling real application challenges, adapting to new safety requirements, and helping customers build quality and reliability into their own products. We see our mission not as fulfilling quotas or rotating stock, but as continually raising the standard for what this copper complex can accomplish in the world.
