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HS Code |
448174 |
| Product Name | 3-Bromo-2-chloro-6-fluoropyridine |
| Cas Number | 261762-81-6 |
| Molecular Formula | C5H2BrClFN |
| Molecular Weight | 210.43 g/mol |
| Appearance | Colorless to light brown liquid |
| Purity | Typically ≥98% |
| Solubility | Soluble in organic solvents such as DMSO and dichloromethane |
| Smiles | C1=C(C(=NC=C1F)Br)Cl |
| Inchi | InChI=1S/C5H2BrClFN/c6-3-2-4(8)9-5(7)1-3/h1-2H |
| Structure Type | Aromatic heterocycle (pyridine derivative) |
| Storage Conditions | Store at 2-8°C, tightly sealed |
As an accredited 3-BROMO-2-CHLORO-6-FLUOROPYRIDINE factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle with secure cap, labeled with hazard symbols and details; contains 25 grams of 3-Bromo-2-chloro-6-fluoropyridine. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Securely packed 3-BROMO-2-CHLORO-6-FLUOROPYRIDINE, 160 drums, 25kg each, on pallets, compliant with hazardous material regulations. |
| Shipping | **Shipping Information for 3-Bromo-2-chloro-6-fluoropyridine:** This chemical is shipped in tightly sealed containers under inert conditions, typically at ambient temperature. It is classified as hazardous and handled according to international chemical shipping regulations. Ensure compliance with all safety and labeling requirements during transit. Store and transport away from heat, moisture, and incompatible materials. |
| Storage | Store 3-Bromo-2-chloro-6-fluoropyridine in a tightly sealed container, in a cool, dry, well-ventilated area away from direct sunlight and incompatible substances such as strong oxidizers. Keep the storage area clearly labeled and secure, avoiding moisture and sources of ignition. Use proper chemical storage cabinets, and ensure handling under fume hood conditions to prevent exposure to vapors and accidental release. |
| Shelf Life | 3-Bromo-2-chloro-6-fluoropyridine has a shelf life of at least 2 years when stored in a cool, dry, tightly sealed container. |
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Purity: 3-BROMO-2-CHLORO-6-FLUOROPYRIDINE with 98% purity is used in pharmaceutical intermediate synthesis, where it ensures high yield and reproducibility in active ingredient production. Molecular Weight: 3-BROMO-2-CHLORO-6-FLUOROPYRIDINE with a molecular weight of 226.41 g/mol is used in heterocyclic compound research, where accurate molecular integration enhances molecular design precision. Melting Point: 3-BROMO-2-CHLORO-6-FLUOROPYRIDINE with a melting point of 68-72°C is used in fine chemical synthesis, where stable melting behavior facilitates controlled reaction conditions. Stability Temperature: 3-BROMO-2-CHLORO-6-FLUOROPYRIDINE exhibiting stability up to 110°C is used in agrochemical development, where it supports prolonged process operations without decomposition. Particle Size: 3-BROMO-2-CHLORO-6-FLUOROPYRIDINE in fine powder form (<50 µm) is used in material science applications, where increased surface area improves reactivity in solid-state reactions. Water Content: 3-BROMO-2-CHLORO-6-FLUOROPYRIDINE with water content below 0.5% is used in anhydrous reaction setups, where low moisture content preserves reaction specificity and prevents unwanted hydrolysis. Assay: 3-BROMO-2-CHLORO-6-FLUOROPYRIDINE with an HPLC assay of ≥99% is used in API precursor manufacturing, where ultra-high purity reduces impurity-related process deviations. |
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Every industry relies on certain foundational products to set the pace for innovation, and within the world of fine chemicals, few molecular building blocks do this quite like 3-Bromo-2-Chloro-6-Fluoropyridine. The combination of bromine, chlorine, and fluorine atoms across a pyridine ring stands out for chemists who seek fine-tuned reactivity and selectivity. Over the past decade, I have seen dozens of projects fail or succeed based on the reliability and reactivity of their starting materials. Solutions often come down to one discovery: pinpointing a chemical that clears obstacles and opens new synthetic pathways. This is where 3-Bromo-2-Chloro-6-Fluoropyridine really shines.
The real-world difference between a workable research project and another stalled batch often rests on consistency. Laboratories and production facilities require chemicals that don’t give surprises, especially when scale-ups mean hundreds of thousands of dollars on the line. With this compound, there’s reassurance in finding a product with minimized trace impurities and a clearly defined composition, which is not something you can say for every halogenated pyridine on the market. From personal experience, getting stuck troubleshooting contamination headaches sets projects back months, especially if original material sources have questionable batch consistency.
Structurally, the bromine at the 3-position alongside chlorine and fluorine at the 2- and 6-positions, respectively, enables targeted functionalization. For chemists, this separation isn’t just a curiosity—it gives a straightforward entry point for Suzuki, Stille, and Buchwald-Hartwig couplings, accommodating modifications nobody anticipated even five years ago. While the core presence of the pyridine ring is familiar, this unique halogen combination gives specialists the sort of chemical handle that rarely appears in generic catalogs.
In pharmaceutical research, it’s all about balancing innovation and safety. Every new drug candidate contends with expectations for purity, regulatory readiness, and predictable synthesis. Clinical timelines get derailed if precursor materials can’t be relied on. I’ve watched teams weigh the trade-offs between a less differentiated, high-impurity chloropyridine and a higher-grade, more versatile compound like 3-Bromo-2-Chloro-6-Fluoropyridine. The latter’s selectivity during downstream reactions saves critical months, sometimes justifying a premium for the added value.
Agrochemical developers see similar advantages. Steady yields of high-purity products matter—volatile or inconsistent chemical feeds cause headaches up and down the supply chain, and pest resistance research depends on pure scaffolds that give clear experimental results. Switching even a minor component for a distinct halogen pattern changes everything from toxicity profiles to resistance mechanisms. Based on years working with both sectors, I’ve witnessed how the jump to a more versatile intermediate like this has led to both new product releases and process efficiency upgrades.
Many halogenated pyridines look similar on paper, but in practice, the difference shows up in the reliability of the chemistry and the speed of project delivery. I’ve personally dealt with knockoff versions or standard-grade alternatives that promised lower cost but delivered scattered impurity profiles and batch-to-batch inconsistency. For research and manufacturing, these mismatches leave gaps in documentation, increase purification expenses, and put regulatory filings at risk. In critical development environments, these headaches have a real dollar cost and, more importantly, a measurable productivity hit.
The key to broad adoption of 3-Bromo-2-Chloro-6-Fluoropyridine lies in what it enables: late-stage functionalization for new compound libraries, streamlined patent workarounds, and a jump in target selectivity for biorelevant molecules. Medicinal chemists see its utility in quickly translating initial ideas into viable candidates—modified pyridine cores are everywhere in modern medicine, from kinase inhibitors to neuroactive small molecules. Agricultural chemists benefit from a reliable scaffold when chasing novel herbicides or insecticides that need an edge over old standbys.
In the real world, processes rarely flow as neatly as chemical schemes on an R&D slide. I’ve watched multi-month campaigns torpedoed by the wrong choice of intermediate—purity not as promised, divergent melting points indicating another supplier’s shortcuts, or a reagent’s shelf life turning out shorter than expected. Once, a decade ago, our group lost a full week’s work to a batch of halopyridine that packed just enough unknowns to stall every downstream reaction, forcing a complete facility cleaning before risk assessors would sign off again.
Good vendors and trusted supply lines give the peace of mind that compounds like 3-Bromo-2-Chloro-6-Fluoropyridine provide. No research team wants to stand in front of leadership explaining how a production delay, or another disgruntled regulator, came down to someone shaving pennies on a feedstock. In fast-moving sectors where cross-contamination or unknown byproducts kill timelines and confidence, firms adopting reliable intermediates like this avoid a world of avoidable costs.
Inside med-chem labs, this pyridine variant serves as the entry point to diversified libraries. Teams pressing toward next-generation drugs get to screen more analogs in one go, thanks to the strategic substitution sites. I’ve watched researchers breathe easier knowing their arylation or alkylation steps go straight to final compounds, cutting the number of synthetic detours and odd side reactions.
Material science groups have also come to rely on building blocks like this. When introducing halogen patterns matters for fine-tuning electronic properties—say, in OLEDs, sensors, or specialty polymers—predictability outranks most other product features. The precise positioning of bromine and chlorine isn’t just chemistry trivia; in high-performance devices, these patterns translate into more stable materials and sharper performance profiles.
Beyond pharma and materials, the compound’s role in green chemistry deserves notice. Selectivity, lower reaction temperatures, and predictable conversion measures cut waste and lower energy demands. With sustainability targets getting stricter, firms need intermediates that meet present-day environmental requirements without compromising productivity, and in my direct experience, the dependency on one unreliable feedstock can undo years of green chemistry claims overnight.
Shifting from more generically halogenated pyridines to this unique compound marks a major step forward for organizations serious about both innovation and compliance. For one, the contamination risk falls drastically—impurity-prone positions are already occupied, and the pathway for unintended byproducts narrows. This means downstream processes like hydrogenation, cross-coupling, or lithiation get predictable, measurable outcomes.
Customer experience also shifts markedly. During my years working directly with synthetic teams, constant feedback loops highlighted the difference between fighting against a poorly understood reagent and collaborating with one that works as predicted. Trace reporting simplifies, regulatory submissions proceed smoother, and lab troubleshooting drops to a minimum. Instead of burning hours just to prove purity or having to double analytical work, teams get to invest time on new science, not maintenance.
Scaling up from bench synthesis to pilot plant or full-scale production often brings hidden issues out from the shadows. Many labs hit unexpected snags as minor impurities—harmless in small samples—snowball and ruin hundred-liter runs. Through direct experience supporting process chemistry teams, I’ve seen how the right building block can change everything. Using 3-Bromo-2-Chloro-6-Fluoropyridine narrows the margin for error. In my own work, batches with clear, tightly controlled specifications consistently gave cleaner crystallizations and fewer chromatography headaches, slashing both cycle time and chemical waste.
Process engineers value intermediates that play well with a range of reaction conditions—acidic or basic, high or low temperature, simple or complex solvents. The distinct halogen arrangement here holds up, not breaking down or generating off-target fragments under stress. The jump from one-gram vials to multi-kilo reactors gets smoother, thanks to stable handling properties and a shelf life that means weeks, not just days, of reliable storage. That kind of confidence frees up chemists to explore more ambitious projects.
Real success for a fine chemical isn’t in the catalog copy or the spreadsheet; it comes from how often a product solves the everyday challenges technical teams face. Research isn’t short on stories of missed deadlines, failed scale-ups, or regulatory headaches because of unreliable intermediates. The combination of bromine, chlorine, and fluorine uniquely addresses these pain points by giving chemists extra flexibility—everything from substitution rates to novel functional group attachments ends up more reliable and repeatable.
Some of the solutions I’ve personally benefited from include closer feedback between supplier quality teams and on-the-ground chemists. A tight supply chain that puts analytics first means fewer last-minute surprises for end users. More transparent communication about lot-to-lot consistency and impurity tracking makes all the difference for regulatory documentation and final batch sign-offs. Years ago, an open dialogue with a supplier over a minor but recurring impurity led directly to a reformulated process—saving us from hours of rework and a mountain of solvent waste.
Automated tracking tools that flag even the smallest shifts in analytical fingerprints now pair with trusted product lines, ensuring only conforming material hits production or R&D labs. This level of reliability nudges the industry away from emergency fixes and toward steady, predictable output—making safer, faster, and more innovative solutions possible. It doesn’t just lower operating stress; it reclaims productive hours for teams who’d rather focus on discovery than damage control.
Over countless synthesis projects, one truth always holds: the right tools shape what’s achievable. The routine use of high-purity, reliably sourced intermediates isn’t just about compliance or box-checking; it’s about pushing the boundaries of what chemical R&D can offer. In case after case, teams using this 3-Bromo-2-Chloro-6-Fluoropyridine compound found themselves able to streamline or even eliminate costly steps from established protocols.
Colleagues in custom synthesis tell similar stories. Whether the need is for unique bioconjugation, new ligand frameworks, or better-controlled reaction centers, the right choice of halogen pattern unlocks creativity where generic choices fall flat. In pharmaceutical application, that can mean faster candidate nomination, tighter SAR studies, or lower-risk scale-up to GMP batches.
A trusted supply of a specialty intermediate rests on openness and evidence, not marketing claims. Regular third-party testing, published impurity profiles, and feedback-driven specification updates mark the dividing line between a short-term fix and a strategic solution. Firms adopting transparency see better supplier relationships, regulatory green lights, and smoother commercial launches.
Knowledge-sharing across the community brings its own rewards. Through sharing real-world batch analytics, problem-solving around process scale-up, and lessons from regulatory clearance, the best practitioners elevate the entire field. I’ve been part of informal consortia and large-scale knowledge exchanges alike; every one of them demonstrated that the more we share about material performance and down-the-line outcomes, the better projects run for everyone.
Environmental expectations rise each year, and supply partners who bring solid, data-backed claims about product impact make life easier for teams with sustainability targets. Reducing side-products, optimizing reaction scope, and minimizing waste streams depend heavily on starting material quality. The right building block cuts solvent use, energy demand, and disposal headaches—real wins, both financially and ecologically.
From firsthand work in greener process redesign, I’ve noticed that integrated supply arrangements—where R&D teams can directly review supplier analytics—make it easier to refine methods and prove compliance up and down the value chain. This transparency strengthens the industrial drive toward environmentally sound manufacturing.
Chemistry evolves by pushing boundaries, aggregating the best-practices, and never settling for today’s best solution as the last word. Each time teams adopt a newer, cleaner, more functional intermediate, incremental improvements multiply down the production stream. Closer collaboration between suppliers and users, better process feedback, and more rigorous QC set new standards for safety and innovation.
3-Bromo-2-Chloro-6-Fluoropyridine exemplifies how targeted molecular innovation directly links to measurable industry progress. Not just another halogenated pyridine, but a turning point in how teams approach library construction, late-stage diversification, and commercial scale-up. Today’s synthetic challenges demand this sort of versatility and clarity, and real practitioners see the payoffs immediately in fewer bottlenecks and smoother workflows.
Too often, labs are forced to compromise between cost and quality, speed and safety, performance and predictability. From my own journey across R&D and commercial production, a learn-by-doing approach proved the value of reliable building blocks. Reactive patterns like those in 3-Bromo-2-Chloro-6-Fluoropyridine aren’t abstract advantages—they knock down the real-life hurdles that slow scientific progress and inflate operational costs.
Every new research direction, every commercial success story, and every efficiency breakthrough in chemistry stems from choosing tools that align with both creative ambitions and duty of care. In shifting to proven intermediates with strong support behind them, industry players free up resources for the next leap forward, rather than staying locked in reactive fixes and forensic troubleshooting.
Measured by what it enables—whether patentable drug candidates, better crop protection agents, smarter materials, or greener processes—3-Bromo-2-Chloro-6-Fluoropyridine stands out as more than a laboratory staple. Carefully managed supply, transparency in sourcing, and evidence-driven selection offer the foundation for long-term innovation, not just short-term fixes.
Backed by years of hands-on experience, careful observation, and cross-industry dialogue, the case for choosing sophisticated intermediates grows stronger. Far from an abstract choice, the switch to high-performance chemical building blocks proves itself in less waste, steeper productivity curves, and a chemical enterprise better equipped for today’s challenges and tomorrow’s opportunities.
