|
HS Code |
470023 |
| Iupac Name | 2,3-Dichloro-5-(trifluoromethyl)pyridine |
| Cas Number | 69045-84-7 |
| Molecular Formula | C6H2Cl2F3N |
| Molecular Weight | 217.99 |
| Appearance | Colorless to light yellow liquid |
| Boiling Point | 175-177°C |
| Melting Point | - |
| Density | 1.549 g/cm3 |
| Purity | Typically ≥98% |
| Solubility | Slightly soluble in water; soluble in organic solvents |
| Refractive Index | 1.487 |
| Flash Point | Unstable at high temperatures |
| Smiles | C1=CC(=NC(=C1Cl)Cl)C(F)(F)F |
| Inchi | InChI=1S/C6H2Cl2F3N/c7-4-1-3(6(9,10)11)2-12-5(4)8/h1-2H |
As an accredited 2,3-Dichloro-5-(trifluoromethy)pyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 250 grams of 2,3-Dichloro-5-(trifluoromethyl)pyridine, with secure screw cap and hazard labeling. |
| Container Loading (20′ FCL) | 20′ FCL loads about 13 metric tons of 2,3-Dichloro-5-(trifluoromethy)pyridine, securely packed in drums or IBCs. |
| Shipping | **Shipping Description:** 2,3-Dichloro-5-(trifluoromethyl)pyridine should be shipped in tightly sealed containers, protected from moisture and incompatible substances. It must be labeled according to hazardous materials regulations. Transport via ground or air must comply with local and international chemical shipping guidelines, including appropriate hazard communication and documentation. Store in a cool, dry, well-ventilated area. |
| Storage | 2,3-Dichloro-5-(trifluoromethyl)pyridine should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from incompatible substances such as strong oxidizing agents. Keep it away from sources of ignition and direct sunlight. Ensure proper labeling and access only to trained personnel. Use secondary containment to prevent spills or leaks. |
| Shelf Life | 2,3-Dichloro-5-(trifluoromethyl)pyridine has a typical shelf life of 2–3 years when stored in a cool, dry, airtight container. |
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Purity 99%: 2,3-Dichloro-5-(trifluoromethy)pyridine with 99% purity is used in pharmaceutical intermediate synthesis, where it ensures high yield and minimal byproduct formation. Melting Point 52°C: 2,3-Dichloro-5-(trifluoromethy)pyridine at a melting point of 52°C is used in agrochemical active ingredient formulation, where it enables precise dosage control in solid-state processing. Stability Temperature 120°C: 2,3-Dichloro-5-(trifluoromethy)pyridine with stability up to 120°C is used in specialty chemical manufacture, where it maintains structural integrity during high-temperature reactions. Particle Size <10 μm: 2,3-Dichloro-5-(trifluoromethy)pyridine with particle size less than 10 μm is used in catalyst development applications, where it provides enhanced dispersion and catalytic efficiency. Moisture Content <0.2%: 2,3-Dichloro-5-(trifluoromethy)pyridine with moisture content below 0.2% is used in electronic materials synthesis, where low water content prevents hydrolysis and ensures product consistency. |
Competitive 2,3-Dichloro-5-(trifluoromethy)pyridine prices that fit your budget—flexible terms and customized quotes for every order.
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Every time a new lot of 2,3-Dichloro-5-(trifluoromethyl)pyridine leaves our facility, we know exactly what has gone into it, who monitored the batch, and how it takes on its role in the chemical industry. Experience tells us this compound isn’t something just anyone can handle with confidence. We have honed our production stream after years of working with pyridine derivatives, focusing on both process reliability and reproducibility. Watching skilled operators move through the crystallization process, seeing the changes in color and texture as the mixture reacts — there’s pride in the technical know-how that flows through every ton. Exposing the product to the right conditions during drying, keeping an eye on potential impurity formation, all these steps require attention that comes only with practice.
The chemical structure of 2,3-Dichloro-5-(trifluoromethyl)pyridine may look simple on paper, but it’s anything but simple to make. With its two chlorine atoms on the pyridine ring and a trifluoromethyl group anchoring the structure, the molecule carries both electron-withdrawing and halogen characteristics. This blend opens up multiple opportunities for reaction and transformation downstream, making this compound a favorite among those who work on agrochemical synthesis and pharmaceutical intermediates. These structural elements change how it behaves — not just with reagents but also in storage and handling. We’ve tracked the changes at every stage, meeting strict quality checks from raw material arrival to final product shipment.
Over years of operation, we’ve established the model for this product — purity standards above 98%, immediate identification with a lot number that carries a full production story, and physical analysis that confirms its authenticity. Moisture control, melting point checks, and HPLC profiles serve as front-line indicators for batch consistency. Each lot has its own minor variances, depending on season, supplier, and process tuning, but we maintain our acceptance criteria without compromise. Too little attention at any stage means trouble for users, so we take these numbers seriously. Standard appearance comes as an off-white to pale yellow solid, easy to handle but never underestimated for potential health and safety risks.
Producing high-purity 2,3-Dichloro-5-(trifluoromethyl)pyridine doesn’t just happen by following instructions — it happens by anticipating problems. Over the years, our technicians have learned to recognize batch behavior: viscosity changes signal a shift in crystallization; subtle odors indicate underlying issues; yield drops can point to shifting raw material quality. Without hands-on knowledge, much goes unseen. We use data analysis at every run, yet nothing replaces direct experience. When process engineers discuss how to tune solvent ratios or optimize phase separation, they reference real problem-solving sessions on the floor. This practical rigor shapes the product more than any published guideline.
Many buyers ask about the targeted uses of 2,3-Dichloro-5-(trifluoromethyl)pyridine. Most people in the chemical trade know its value as an intermediate in pesticide and pharmaceutical synthesis. The behavior of the trifluoromethyl group in the molecule matters to those who want to introduce this motif further down their process route. Our customers have explained how the product integrates into their own synthetic routes, allowing substitution reactions or coupling steps to build more complex molecules. Some incorporate it into their lead development projects for new actives. Others count on the robust nature when handling scale-ups beyond small lab runs. Over time, these real-world stories have flowed back to us, deepening our understanding of the performance needed at every scale. Whenever a new request comes in — whether for a few kilograms or a whole truckload — technical discussions dig into solubility, reactivity, and contaminant management.
A single impurity in this compound may look innocuous, yet that one molecule can shift a synthesis path, reduce crop protection yield, or cause a drug intermediate to miss regulatory limits. At plant scale, we test each run against both customer requirements and our own historical data sets. Tracking contaminants requires vigilance. We see how different sources of raw materials can result in slight variations of halogen content or introduce foreign substances — all of which can affect both yield and downstream safety. The best results come from those who track every parameter: reactor temperature holding, solvent drying quality, atmospheric humidity, and even the batch order in the week’s production schedule. Day after day, the outcome proves the theory: If diligence slips, performance slips with it. Experience also taught us not to ignore small details, since downstream users notice even minor inconsistencies that others might miss.
Over the past decade, we’ve scaled production from lab flasks to full-scale reactors. In the early days, errors in temperature or pressure led to unplanned by-products and lower yields. Seasonal shifts affected cooling water temperatures, and that led to subtle differences in crystallization patterns. Correcting these requires flexible thinking and a willingness to experiment. Today, each production run follows a working recipe cemented by process improvements gained from real trouble on the line. Order changes, maintenance delays, and even regional weather can leave their mark. The team now understands that every parameter — from batch size to solvent charge, filtration speed to final drying — matters to the outcome. Consistency grows not from rigid control alone but from people who recognize warnings before numbers start to drift.
People often ask how 2,3-Dichloro-5-(trifluoromethyl)pyridine stacks up against related pyridine compounds. Technically, the twin chloro groups confer reactivity toward both nucleophilic substitution and palladium-catalyzed coupling. In comparison to other dichloropyridines lacking trifluoromethyl, we see increased stability and unique reactivity, opening doors for new chemical pathways. The trifluoromethyl group itself makes the product attractive for those after electron-withdrawing effects in building target molecules — particularly in crop protection chemistry, where this motif influences both activity and environmental profile. Handling this product is more predictable than some higher-halogenated relatives, which can form gums or sticky residues during processing. Over years of direct handling, operators have gained confidence in its solubility and cleaning behavior.
Producers face more than just synthesis: safe storage defines real-world usefulness. 2,3-Dichloro-5-(trifluoromethyl)pyridine behaves well if kept dry, sealed, and protected from direct sunlight. Factory teams monitor humidity constantly; uncontrolled absorption can cause clumping or gradual hydrolysis. Proper container selection reduces the risk of leachables, maintaining purity for longer. Shipping teams coordinate with logistics providers, making sure each package endures varying climates and extended storage without loss of quality. Even the best-made material degrades if care breaks down at this stage. Quality inspectors open each shipment, sample contents, log observations, and compare against the original batch fingerprint, catching issues before product reaches customer lines.
Over many years of direct discussion with users, real feedback shapes the way we produce and evaluate this compound. Some customers optimize their own processes to match our material's specific characteristics, requesting occasional tweaks for solubility or particle size. Others want tighter impurity profiles. Every special request brings a new technical puzzle, prompting our teams to adjust both analytical testing and, sometimes, synthetic routes. Open communication allows us to trace issues back to root causes, whether in our own process or in a user’s downstream tank. Our reputation rests on handling these exchanges openly and quickly, turning mutual trust into ongoing improvement that gets measured batch after batch.
We have always believed that technical support doesn’t stop once a barrel leaves the loading dock. Our experienced chemists help partners interpret analysis data and solve compatibility issues at their own plants. Occasionally, teams send samples back for further testing; we run full suite analyses using the same equipment that validates each batch before shipment. Internal teams keep records of recurring questions — from solvent choice to mixing order — to catch any sign that a recurring trend might affect future supply. Long-term relationships with users often begin with direct troubleshooting, whether in personal visits or realtime video, showing both sides of the partnership.
Sustainable production grows more urgent as regulatory and customer demands shift. Over time, we’ve seen how process efficiency and environmental impact entwine with business operations. Plant emissions monitoring, solvent recycling steps, and water reuse allow us to cut down waste. We invest in capture and abatement systems that protect both the workplace and the wider community. Technical teams adapt synthesis to reduce waste, using alternate feeds where feasible. Many improvements start in response to direct operating experience; unexpected waste streams or a change in local legislation can prompt significant upgrades. Every change brings its own set of lessons, and not every test run goes as planned. By keeping lines of communication open between process engineers and front-line workers, we reach better solutions faster.
A single weak point on the production line — whether equipment failure, raw material variability, or staff rotation — can affect the product’s consistency. Regular maintenance, robust training, and tight supplier management provide the foundation for every successful batch. Machinery tells its own story; odd vibrations, small temperature deviations, or leaks can indicate bigger problems below the surface. During audits, both customer and regulatory, we walk visitors through the process, pointing out not just what works, but what we’ve learned from past failures. Inspectors respect openness forged through operating experience, recognizing that excellence depends on honest feedback, not just paperwork.
Even the best-run operation encounters surprises. Once, during a sudden spike in demand, supply chain delays left us with raw materials that fell outside usual spec. Process adjustments made up for some of the gap, but batch yields dipped temporarily, setting off a review that changed how we qualify suppliers. In another case, equipment failure shut down a reactor, forcing a mid-run transfer to a spare vessel. We salvaged most of the run by drawing on years of troubleshooting. Each event leaves a mark, teaching teams how to anticipate, respond, and document each recovery. Sharing lessons with customers reassures them that the knowledge gained becomes part of the ongoing process, not just a fix for a one-off problem.
Staying ahead of changing regulatory demands causes as many headaches as it solves. Each region calls for its own registration and reporting standards, pushing us to maintain extensive documentation, meet traceability needs, and provide product transparency on demand. Updates can arrive quickly, changing acceptable impurity thresholds or mandating new safety reporting. Navigating these requirements calls for well-trained staff who follow both international standards and local compliance needs. Internal systems log each raw material, process adjustment, and analytical result, creating a robust record for both regulatory and end-user review. By actively tracking these trends, the team prepares for each change, lessening disruption and keeping stakeholders informed.
Thanks to input from academic partners and end-users, we consistently pursue product evolution. In the last few years, new methods of synthesis have cut down on hazardous reagent use and improved selectivity for target isomers. We invest in laboratory-scale research, translating findings into trial runs at plant scale before full integration. Laboratory teams revisit existing procedures, searching for process steps that contribute most to impurity generation or energy consumption. Through analytical advances — better chromatographic separation, spectroscopy updates — staff catch outliers before they turn into problems. Research is only as valuable as the skill used to implement it, and plant managers support ongoing education and training, making sure today’s solutions stay relevant as demand shifts.
Each customer story tells us something new. One partner developed a new synthetic path using our product, reporting back increased throughput and a gain in final product yield. More feedback points to greater handling ease after we improved drying stages and repackaged for better flow. Some found that minor tweaks in heating conditions led to a smoother integration in their reactors. Others discovered that blending our material with select solvents led to fewer unplanned side reactions — observations we shared with other users facing similar issues. Knowing that real-world experience matters more than sales brochures drives us to ask questions, document findings, and work side-by-side with users who see the product not just as a chemical, but as a cornerstone of their processes.
2,3-Dichloro-5-(trifluoromethyl)pyridine rewards those who put in the effort at every stage. From the manufacturing floor to the user’s own reactors, success grows from clear communication, technical attention, and the willingness to act on lessons learned. We find value in each interaction, knowing that the challenge of making and delivering a reliable product rests on building trust as much as chemical skill. As process technologies evolve and new demands appear, our commitment stands on continuous improvement, technical transparency, and a focus on practical, people-driven solutions at every step.
