|
HS Code |
570501 |
| Chemical Name | Pyridine, 2-bromo-5-(trifluoromethyl)- |
| Cas Number | 694-32-6 |
| Molecular Formula | C6H3BrF3N |
| Molecular Weight | 225.99 g/mol |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | 194-197 °C |
| Density | 1.68 g/cm³ |
| Solubility | Slightly soluble in water |
| Refractive Index | 1.519 |
As an accredited Pyridine, 2-bromo-5-(trifluoromethyl)- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle, 25 grams, sealed with a PTFE-lined cap; features hazard labels and product details printed on a white label. |
| Container Loading (20′ FCL) | 20′ FCL container typically loads 80-100 drums (200 kg each) of Pyridine, 2-bromo-5-(trifluoromethyl)-, totaling 16-20 MT. |
| Shipping | Pyridine, 2-bromo-5-(trifluoromethyl)- must be shipped as a hazardous chemical, typically in secure, sealed containers. It should comply with regulations for flammable and toxic substances, including appropriate labeling and documentation. Transport may require additional packaging to prevent leaks, and it should be handled by trained personnel following safety guidelines. |
| Storage | Store 2-bromo-5-(trifluoromethyl)pyridine in a cool, dry, and well-ventilated area, away from sources of ignition, heat, and incompatible materials such as strong oxidizing agents. Keep the container tightly closed when not in use, and store in a chemical-resistant container. Use secondary containment to prevent leaks or spills. Ensure proper labeling and restrict access to authorized personnel only. |
| Shelf Life | **Shelf Life:** Store Pyridine, 2-bromo-5-(trifluoromethyl)- in a cool, dry place; typically stable for 2 years in sealed containers. |
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Purity 98%: Pyridine, 2-bromo-5-(trifluoromethyl)- with 98% purity is used in pharmaceutical intermediate synthesis, where high purity ensures optimal reaction yields and minimal by-products. Melting point 48°C: Pyridine, 2-bromo-5-(trifluoromethyl)- with a melting point of 48°C is used in fine chemical manufacturing, where controlled melting facilitates easy incorporation into reaction mixtures. Molecular weight 260.98 g/mol: Pyridine, 2-bromo-5-(trifluoromethyl)- possessing a molecular weight of 260.98 g/mol is used in agrochemical research, where precise molecular characterization supports accurate formulation. Stability temperature up to 120°C: Pyridine, 2-bromo-5-(trifluoromethyl)- stable up to 120°C is used in advanced material synthesis, where thermal stability ensures integrity during high-temperature processing. Water content ≤0.5%: Pyridine, 2-bromo-5-(trifluoromethyl)- with water content below 0.5% is used in organometallic catalysis, where low moisture prevents catalyst deactivation. Appearance (white crystalline solid): Pyridine, 2-bromo-5-(trifluoromethyl)- as a white crystalline solid is used in analytical standards preparation, where consistent physical form aids precision weighing and reproducibility. |
Competitive Pyridine, 2-bromo-5-(trifluoromethyl)- prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615371019725 or mail to sales7@bouling-chem.com.
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Decades in the business of chemical synthesis have taught us that every detail counts, especially in the design and production of fine chemicals such as Pyridine, 2-bromo-5-(trifluoromethyl)-. In our own facilities, we’ve developed approaches that don’t just mirror accepted industry methods — they improve upon them by focusing on real-world outcomes for end-users. Chemistry isn’t only about reactions, it is also about the choices behind every batch. Each parameter, from reagent quality to purification technique, tells a story about the final product you receive.
One thing anyone working with specialty pyridines quickly learns is that purity isn’t a buzzword: it defines how well the compound performs in your process. Trace impurities — even a fraction of a percent — can derail downstream reactions or affect yield. In our own quality labs, purity assessments use advanced GC-MS and NMR methods, making it possible to characterize not just the main product, but even minor byproducts or structural isomers. We have invested in years of continuous improvement and collaborative troubleshooting between the plant floor and the QC department. As a result, we routinely supply material aligned with the highest standards expected by R&D and pilot-scale teams in pharmaceutical and agrochemical development.
There is a tendency in the chemical supply market to view pyridine derivatives as interchangeable commodities—just boxes labeled with a CAS number. From the manufacturer’s perspective, though, direct synthesis means so much more. We select every input ourselves, avoiding variability that sneaks into the supply chain through third-party handling or long-term warehousing. As a result, our product offers unmatched lot-to-lot consistency. End-users in critical synthetic applications notice the difference right away: less rework, better reproducibility, and far fewer surprises.
Model choices stem from practical needs. Over years of working with research chemists, we have tried alternative grades, variable packaging formats, and even custom specifications for 2-bromo-5-(trifluoromethyl)pyridine. This type of hands-on experience shapes the specifications we offer today. Our standard material ships with a minimum assay of 98% determined by HPLC and confirmed by NMR, but the reality is we often meet or exceed this due to newer process controls and extra purification steps.
Packing format can matter just as much as purity. Sensitive intermediates react to their container and closure. Because of feedback from formulation chemists, we shifted away from plastics years ago, offering glass bottles with inert gas headspace for bulk shipments. These decisions, though simple on the surface, come from years of direct customer feedback and our own R&D department’s assessment of typical stability pitfalls in halogenated pyridines.
This compound stands out for a reason. The presence of both a bromine atom and a trifluoromethyl group on the pyridine ring gives a unique combination of reactivity and selectivity. We have witnessed firsthand how medicinal chemistry groups leverage this scaffold to build complex molecules. Facility in halogen-metal exchange, cross-coupling, or nucleophilic aromatic substitution enables rapid assembly of novel chemical entities. For those working in crop protection, the electron-deficient pyridine nucleus opens up options for fine structural modifications to improve bioactivity or adjust environmental stability. Our technical relationship with application chemists means we hear about these challenges every season and adjust our recommendations accordingly.
Over many campaigns, we have faced the realities of scaling up halopyridine synthesis. One commonly encountered issue involves byproduct formation — particularly during bromination or trifluoromethylation stages. We addressed this not through standard templated controls but by investing in onsite analytical support for in-process control, rapid impurity tracking, and direct dialogue between process engineers and chemists. Introducing in-line monitoring and real-time spectroscopic feedback has saved countless batches from costly rework.
Solvents, too, matter. Reproducible crystallization and effective mother liquor separation allow us to consistently reach target product purities without harsh reprocessing or elevated solvent residues. We’ve learned, through tough lessons, that omitting such details can result in off-odors, excessive color, or difficult filtration — all things that users notice immediately, even before analytical verification.
Direct involvement in day-to-day production gives us an edge when meeting evolving regulatory requirements. Ongoing dialogue with compliance experts and real-world assessment of supply chain issues mean we keep an eye on the environmental footprint of our process steps. Whether it relates to solvent recovery, energy optimization, or safe waste handling, we channel our operational experience into measurable improvements. Working with pyridine derivatives frequently means accounting for both human safety and downstream product traceability. Our tracability protocols, raw material source vetting, and open information policies have been shaped by requests from partners who need clear documentation for global filings or environmental audits.
From our vantage at the manufacturing floor, we see which applications of 2-bromo-5-(trifluoromethyl)pyridine stand the test of time. In small-molecule pharmaceutical research, this compound enables the introduction of trifluoromethyl or bromine handles for later cross-coupling — key for exploring SAR in new candidates. Our direct support for biopharma scale-up campaigns lets us anticipate bottlenecks, provide extra technical data, and offer input on likely side reactions. In crop science labs, requests often revolve around rapid functionalization and scale flexibility. We respond by supplying not just small vials but kilogram batches with tight specs, informed by real agricultural chemistry timelines.
Differentiating our product from generic suppliers takes more than quoting a CAS number or running a standard set of purity tests. Where others might source from brokers and treat each lot as fungible, our intimate knowledge of batch histories, impurity profiles, and end-user expectations means we supply more reliable material. In synthetic labs, a difference of one percent in purity can cascade into hours of lost time and failed procedures. Our practice of sharing batch histories, chromatograms, and even tips for handling and storage isn’t marketing speak — it’s born of the relationships we build with bench chemists who need things to work the first time, every time.
As manufacturers, we get the calls from chemists facing stalled couplings, unexpected spots on TLC, or unexplained instability. More often than not, these problems come down to issues with upstream material quality. Drawing on years of batch records, we coach partners through solvent system adjustments, offer second opinions on spectral data, and recommend safe handling to protect sensitive functional groups. Our feedback loop with chemists goes both ways: challenges at the bench drive us to adjust process controls, improve packaging, and refine lot release protocols.
We’ve seen how improper storage ruins a good batch. Temperature, light, and atmosphere all matter. Our warehouse teams follow strict protocols: storing pyridine derivatives under inert gas, away from direct sunlight, and within tight temperature boundaries. End-users routinely ask why our product maintains color and clarity batch after batch — the answer traces back to hands-on warehouse experience, not theory. Feedback about local warehouse conditions or unexpected transit delays prompts us to suggest best practices, like prompt transfer to cool, dry environments and minimizing container openings to block moisture or air ingress.
Lab teams request detailed analytical packages for a reason, often to support drug filings or regulatory submissions. In responding to these requests, we provide comprehensive data sets: NMR spectra, HPLC chromatograms, water content information, and elemental analysis. Years of dialogue with QA and regulatory groups have honed what matters and what doesn’t. We skip filler, focus on what R&D and QA teams want, and always link reports to specific batches. This practice results from walking the line between responsive customer service and knowing what documentation truly strengthens a regulatory case.
Chemistry doesn’t operate in a vacuum, especially as regulations and sustainability benchmarks tighten. Minimizing energy and waste is a real challenge — not just a checkbox. To reduce environmental impact in pyridine synthesis, we retrofitted our bromination reactors to improve yield-per-reactor-volume and lower byproduct formation. We recycle solvents where possible and monitor wastewater for any halogenated organics before neutralization and discharge. Our learnings from early audits and customer reviews now drive a continuous review cycle, making us more prepared for the next round of environmental standards ahead.
Raw material interruptions and logistical challenges can threaten timelines. Only direct producers recognize just how little slack there is in a specialty chemicals supply chain. Demand can spike when new reactions are published, or a big customer places a scale-up order with little warning. Only by running our own production — tuning schedules, qualifying backup suppliers, and maintaining reserve production — do we keep up. We have weathered regional shortages, border issues, and transport disruptions by staying nimble and keeping communication channels tight with both suppliers and customers.
End-users who partner directly with the true manufacturer often return because of the difference it makes. They tell us about critical reactions that ran better, regulatory packages completed faster, or rounds of development shortened, all because the raw material was fit-for-purpose the first time. Our staff doesn’t just process orders — they bring manufacturing, analytical, and regulatory knowledge to every question received. This transfer of experience makes new applications or scale-ups feel manageable, not risky.
Meaningful change rarely comes from the top down, but from the real challenges chemists face daily. Over the years, suggestions from users have driven us to change reagent suppliers, alter purification steps, and update packaging formats. When several partners reported minor instabilities in stored samples, we checked storage conditions, altered product fills, tested for trace metal content, and tracked results in follow-up shipments. These improvements didn’t happen on a single project plan, but through many rounds of trial, documentation, and open dialogue with end-users who notice every detail.
Being a manufacturer means standing behind every batch that leaves our facility, year after year. New customers often arrive skeptical—previous suppliers may have supplied material with variable color, fluctuating purity, or inconsistent documentation. Our goal is to earn trust by letting data and reliability speak for themselves. Inventory, test records, shipment histories, and user feedback all play a part. In a business defined by precision and reproducibility, consistency remains the best proof of value.
The world of chemical manufacturing never stays still. New synthetic chemistry methods, updated reaction conditions, or evolving environmental regulations always bring challenges and opportunities. Our in-house R&D stays close to these trends, proactively devising process modifications and sharing lessons with partner labs. We engage in two-way dialogue, troubleshooting stubborn reaction steps, fielding questions about emerging applications, and contributing what we learn from our own process scale-ups. These partnerships — built on open communication and shared practical experience — drive innovation, reduce surprises, and enable progress on demanding projects.
Producing Pyridine, 2-bromo-5-(trifluoromethyl)- at scale connects tangible details — from feedstock quality, purification practice, and packaging to the actual reaction flask in a user’s lab. Our difference lies not just in how we make chemicals, but in every decision based on first-hand experience and a refusal to settle for good enough. Reliable pyridine derivatives aren’t born in a sales office or a distributor’s warehouse. They come from hands-on manufacturing commitment, transparent communication, and relentless improvement — qualities that every chemist can experience with every batch they receive from us.
