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HS Code |
830836 |
| Chemical Name | 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt |
| Molecular Formula | C5HCl3NNaO |
| Molecular Weight | 222.42 g/mol |
| Cas Number | 72189-33-8 |
| Appearance | White to off-white powder |
| Solubility | Soluble in water |
| Storage Condition | Store in a cool, dry place |
| Ph 1 Solution | Approximately 7-9 |
| Purity | Typically >98% |
| Synonyms | Sodium 3,5,6-trichloro-2-pyridinol |
| Stability | Stable under recommended storage conditions |
| Iupac Name | Sodium 3,5,6-trichloropyridin-2-olate |
| Hazard Classification | Irritant |
As an accredited 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Sealed 100g amber glass bottle with tamper-evident cap, chemical label, hazard symbols, and detailed product information for 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt. |
| Container Loading (20′ FCL) | 20′ FCL: Packed in 25kg PE bags, 10 MT per container, ensuring safe, moisture-proof transport of 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt. |
| Shipping | **Shipping Description:** 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt is shipped in tightly sealed containers, protected from moisture and light. Transport complies with regulatory guidelines for chemicals, ensuring safe handling. Proper labeling and documentation accompany the package, and temperature conditions are monitored to maintain product stability during transit. |
| Storage | 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt should be stored in a tightly closed container, kept in a cool, dry, and well-ventilated area away from incompatible substances such as strong acids and oxidizers. Protect it from moisture and direct sunlight. Ensure proper labeling and keep it out of reach of unauthorized personnel. Store at room temperature unless otherwise specified by the manufacturer. |
| Shelf Life | The shelf life of 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt is typically 2 years when stored in a cool, dry place. |
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Purity 98%: 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt with a purity of 98% is used in agrochemical synthesis, where high purity ensures minimal by-product formation and superior crop protection efficiency. Molecular Weight 216.48 g/mol: 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt with a molecular weight of 216.48 g/mol is used in pharmaceutical intermediates, where precise molecular characteristics enable accurate dosing in novel drug formulations. Solubility in Water 25 g/L at 20°C: 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt with a solubility of 25 g/L at 20°C is used in aqueous formulation processes, where enhanced solubility facilitates rapid dispersion and uniform distribution. Particle Size 100 mesh: 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt at 100 mesh particle size is used in technical-grade powder blends, where fine particulate size improves homogeneity in multi-component mixtures. Stability Temperature up to 80°C: 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt stable up to 80°C is used in high-temperature synthetic reactions, where enhanced thermal stability maintains product integrity during processing. Melting Point 220°C: 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt with a melting point of 220°C is used as a raw material in thermal processing applications, where high melting properties contribute to resistance against decomposition under heat. |
Competitive 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt prices that fit your budget—flexible terms and customized quotes for every order.
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The chemical industry keeps evolving, but there’s a handful of compounds that still manage to draw steady attention. 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt belongs in that group. Out of all the molecules we batch and process, this one keeps teaching us about the importance of reliable quality—especially in pharmaceuticals and agrochemicals. There’s a world of difference between handling this material as a raw supplier and knowing every step of how it’s synthesized, filtered, dried, and handled on-site. One thing years in this business have shown: you spot quality not by the paperwork, but by what comes off your own line.
The nuances show themselves with every batch. Starting with chlorination and moving through neutralization, the stability of the sodium salt form is obvious, especially given the sensitive reactions downstream users want. Only a properly controlled process avoids contamination, so the finished product meets purity levels that hold up under the scrutiny of the market’s toughest players. We know those expectations—ours has gone through the same third-party labs that buyers trust. Specifications change according to needs, but clarity on the traceability and consistency of our product has always been key.
Our typical lot of 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt stands out for its pale to off-white color, good flow, and ease of handling. The sodium salt form gives better solubility than the base compound, and we control particle size to suit what formulators or synthesis teams have come to expect. The physical state matters since caking or moisture uptake during shipment can ruin months of planning—not to mention ruin blends in a downstream tank. Over the years, tightening controls on drying and packaging have led to more reproducible results in high-volume scale-up.
Customers often have strict requirements for purity, especially for cGMP-compliant uses. We deliver material that meets HPLC and GC requirements, while keeping heavy metal levels under tight limits. Having an on-site analytical team makes a huge difference: our feedback loop between the production team and lab is rapid. Abnormal readings don’t wait for a remote office or third-party report. Trace levels of residual pyridine or unwanted halides? They show up before drums leave the site.
Talking with long-term customers puts theory to the test. One of the main drivers for requests comes from the need for intermediates in pesticide synthesis. The pyridine core, tailored with chlorines at the right positions, fits into a variety of agrochemical products aiming to improve yield or pest resistance. Pesticide companies want not just the molecule, but every minor impurity profile spelled out—because reproducibility means scale-up rarely goes smoothly if upstream quality doesn’t hold steady. Some multi-site crop protection businesses run trial syntheses on thirty kilograms and immediately detect any change from a spec update at our end.
On the pharmaceutical side, research teams use 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt as a building block for complex API precursors. Medicinal chemistry relies on reliable feeds. Even a change in polymorph or a low level of sodium chloride contamination can throw off isolation steps downstream or impact regulatory documentation. Documenting batch usability data and stability, we’ve seen how smaller labs avoid headaches by not only analyzing a supplier’s Certificate of Analysis, but by exchanging technical details with us directly. These conversations ensure their synthetic protocols don’t need last-minute rework because of a slight deviation in micron size or moisture content from our plant.
There’s a gap in the broader market between “just making a chemical” and really knowing what each impurity, trace solvent, and polymorphic variant means in the real world. Over time, some partners returned to us after cheaper offerings let them down. Failing a multi-ton batch because a minuscule byproduct crept in highlights how dependent global supply chains are on the basic integrity of manufacturing. No distributor or trader sitting outside the plant can guarantee that. As direct manufacturers, we’ve invested in closed-loop process controls, real-time monitoring, and both qualitative and quantitative release criteria for every lot.
We do not take the easy route of just “meeting minimum.” Since many applications need tailored particle sizes, we handle custom micronization and sieving on-demand. Our process is not locked in stone: after feedback from a pharmaceutical client about filterability, we implemented a dedicated dry room and anti-static protocols to cut down on lumping and uneven distribution, especially during Asian summers. A farming technology customer once pointed out a handling issue when the product was repackaged locally, so we piloted new moisture-barrier packaging that kept the lot inside spec across wider shipping routes.
Not all pyridine derivatives with chloro substitutions will behave the same way. Shifting a chlorine or using a different salt form brings distinct reactivity, toxicity handling, and stability issues. 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt distinguishes itself from either the parent alcohol or the free acid. Chemically, the sodium salt allows far easier dissolution in aqueous media—sought after in both agricultural formulations and pilot API syntheses. For spray or powder blending, this difference saves time and reduces the risk of hot spots or aggregates that wreck otherwise expensive formulations.
Some customers use the free (non-sodium) form, facing recurring storage and handling issues because the raw material is more prone to clumping and less forgiving under humid conditions. Our experience shows that switching to the sodium salt provides a more robust experience. Shelf stability improves, dusting keeps to a minimum, and warehouse operators no longer need to redissolve stubborn cakes. In heated process vessels, too, the sodium form avoids phase separation, making it a favorite for continuous batch operations rather than small manual batches.
Other chloropyridine compounds occasionally appear as cheaper options. These often present less selective chlorination or introduce small positional isomers, which might escape low-resolution analytical methods. Long-term, we found that sticking closely to the recognized structure and practicing tight process control produces a purer end product with a cleaner performance, whether for advanced chemical synthesis or when meeting the strict scrutiny of animal feed approval authorities.
3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt, like many specialty chemicals, needs careful handling and respect for its potent chemistry. Years spent in the plant exposed us to the practical concerns that no technical data sheet fully describes. Dust creation, for instance, depends heavily on particle morphology, drying technique, and even the local humidity at the time of packing. We realized that unsafe dust is less a function of the innate chemical, more of how a batch comes off the line. That is why we focus intensely on upstream process controls, not simply relying on respirators and PPE downstream.
There’s a deeply practical side to in-house manufacturing: every observed near-miss leads to a process tweak, not just paperwork. For example, our pneumatic conveying systems evolve as we notice clogs or filter tears. Faults in packaging become clear not from customer complaints, but from watching our own warehouse staff manage bags and drums daily. As a result, we keep our staff trained to identify batch-to-batch variation, and we stay open to feedback about how real users out on the floor interact with bulk drums and small sacks. This feedback shapes both our safety guidance and how we package future lots.
Tightening environmental rules worldwide have shaped the way we view both the process and the product. Manufacturing 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt once generated significant waste, especially from solvents, water, and off-spec batches. Down the years, we made incremental improvements, from installing closed-cycle water systems to selecting greener process solvents. Specific pushback from European and North American customers pushed us to lower not only absolute emissions, but also to prove absolute traceability in raw material sourcing.
Minimizing off-gassing and liquid discharge required a complete review of our synthesis pathways, not simply adding end-of-pipe solutions. Internally, waste audits tracked every kilogram of byproduct. Where some plants would landfill the secondary streams, we developed downstream uses or sold certain streams as starting materials for smaller industries or research labs. Even packaging choices reflect this: recyclable materials, shipping container re-use, and pallet returns have dramatically cut our shipping-related footprint. We share these statistics transparently so buyers can factor them into their own supply chain reporting.
In practice, the usefulness of a specialty chemical like 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt depends on more than lab data or sales claims. Incoming requests from formulators, researchers, and production engineers often look superficially similar—a desire for a certain purity or mesh size, for example. But the real story comes out once we talk directly. Some need precise throughput data for automated formulation, others care about micro-scale consistency for R&D and pilot studies for innovative pesticides.
Maintaining open technical dialogue matters at every step. In cases where analytical or production details in a user’s application remain confidential, we’ve set up secure, limited-access knowledge-sharing portals to support development teams. Once, a pharmaceutical partner requested accelerated stability testing for an in-development formulation. We ran secondary analytics, adjusted our packaging, and provided test quantities without red tape, so their regulatory filing could proceed without delay. This level of collaboration has been central to our approach, blurring the old lines between supplier and true partner.
Market demand for chlorinated pyridine derivatives runs in cycles, affected by broader regulatory, patent, and environmental developments across the globe. Regulatory agencies move fast, prompting sudden shifts in demand or even discontinuation of specific applications. As local upstream supply networks in Asia and South America tighten, procurement teams look for security in origin, logistics, and backup stock. We watch trends not just from order books, but from the periodic requests for non-standard grades, emergency shipments, or unusual documentation from anxious compliance teams.
Our unique position as manufacturer means we can ramp up or scale down operations in response to these swings, not only to maintain customer supply but also to keep our own staff and local partners working safely and efficiently. During periods of raw material shortage, rather than passing risk to our customers, we pre-qualify multiple procurement pathways and pool information with other direct processors. That agility has allowed us to maintain unbroken supply even through unexpected lockdowns and logistics disruptions.
In the last years, we have seen tighter restrictions on certain uses of pyridine compounds in crop protection, prompting a rise in research for alternative molecules and lower-residue synthesis routes. As needs change, our role as manufacturer gives us early warning on which next-generation materials or derivatives require new development and where our core sodium salt will retain its place. We support such transitions, working side-by-side with researchers to jointly troubleshoot synthesis or regulatory questions using our hands-on data and operational experience.
Batch returns have become less frequent, but each one carries its own lessons. Once, a shipment destined for a northern climate failed during winter storage—excess condensation caused surface caking in bags that held up under previous, warmer conditions. From that episode, we redesigned packaging, improving moisture barrier seals and batch trace coding, so issues could be tracked to the hour, not just the day or shift. Situations like these never turn up in idealized product data sheets but come from walking the receiving dock, talking to users, or troubleshooting by phone at odd hours.
Other incidents taught us that a one-size-fits-all mindset never works. An agrochemical user needed high-throughput filling with minimal dust, while a pharmaceutical blender found that even micro-fines caused scale buildup on expensive tablet presses. We reconsidered particle size distributions and post-reaction drying limits. For both, adjustments not only fixed user problems but helped tune our process controls tighter, improving the final product for every customer down the line.
Every metric, from safety to environmental compliance to customer satisfaction, flows from constant awareness of what actually works in the field. We do not see ourselves as simply producing a commodity, but as an active technical partner for those who stake their own systems—and often reputations—on every ton they take in. 3,5,6-Trichloro-Pyridine-2-Ol Sodium Salt may have a detailed chemical name, but its reputation derives from how it performs under real-world pressure, in the hands of teams beyond our gates. Our experience has proven that real quality comes from closing the feedback loop and staying invested in every outcome—from synthesis line to finished application.
