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HS Code |
690628 |
| Product Name | 2-Chloro-5-nitro-3-(trifluoromethyl)pyridine |
| Cas Number | 3939-09-1 |
| Molecular Formula | C6H2ClF3N2O2 |
| Molecular Weight | 228.54 |
| Appearance | Yellow to orange crystalline powder |
| Melting Point | 61-64°C |
| Density | 1.64 g/cm3 (approximate) |
| Solubility | Slightly soluble in water; soluble in organic solvents like DMSO and DMF |
| Purity | Typically ≥98% |
| Synonyms | 2-Chloro-5-nitro-3-trifluoromethylpyridine; 3-(Trifluoromethyl)-2-chloro-5-nitropyridine |
| Smiles | C1=CN=C(C(=C1Cl)[N+](=O)[O-])C(F)(F)F |
As an accredited 2-CHLORO-5-NITRO-3-(TRIFLUOROMETHYL)PYRIDINE factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 250g of 2-Chloro-5-nitro-3-(trifluoromethyl)pyridine supplied in a tightly sealed amber glass bottle with hazard labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Loaded with 12 MT packed in 480 fiber drums, each containing 25 kg net of 2-chloro-5-nitro-3-(trifluoromethyl)pyridine. |
| Shipping | 2-Chloro-5-nitro-3-(trifluoromethyl)pyridine is shipped in tightly sealed containers, protected from moisture, heat, and direct sunlight. It should be handled and transported according to local, national, and international regulations for hazardous chemicals. Ensure packaging is compliant with UN transportation guidelines to prevent leakage or accidental exposure during transit. |
| Storage | Store 2-Chloro-5-nitro-3-(trifluoromethyl)pyridine in a tightly closed container in a cool, dry, and well-ventilated area, away from sources of ignition, heat, and incompatible materials such as strong oxidizers and bases. Keep out of direct sunlight. Handle in accordance with standard laboratory safety protocols, and use appropriate personal protective equipment to prevent contact and inhalation. |
| Shelf Life | Shelf Life: 2-Chloro-5-nitro-3-(trifluoromethyl)pyridine remains stable for at least 2 years when stored in a cool, dry place. |
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Purity 98%: 2-CHLORO-5-NITRO-3-(TRIFLUOROMETHYL)PYRIDINE with purity 98% is used in pharmaceutical intermediate synthesis, where high compound integrity enhances final product yield. Melting Point 68°C: 2-CHLORO-5-NITRO-3-(TRIFLUOROMETHYL)PYRIDINE with melting point 68°C is used in agrochemical manufacturing, where thermal stability during formulation ensures minimal degradation. Particle Size < 50 µm: 2-CHLORO-5-NITRO-3-(TRIFLUOROMETHYL)PYRIDINE of particle size less than 50 µm is used in catalytic process development, where increased surface area improves reaction kinetics. Moisture Content < 0.5%: 2-CHLORO-5-NITRO-3-(TRIFLUOROMETHYL)PYRIDINE with moisture content below 0.5% is used in electronic chemical processing, where low humidity prevents undesired side reactions. Stability Temperature up to 120°C: 2-CHLORO-5-NITRO-3-(TRIFLUOROMETHYL)PYRIDINE stable up to 120°C is used in specialty material synthesis, where thermal endurance ensures consistency in high-temperature operations. Assay ≥ 99%: 2-CHLORO-5-NITRO-3-(TRIFLUOROMETHYL)PYRIDINE with assay greater than or equal to 99% is used in high-purity API production, where superior analytical accuracy assures compliance with quality standards. |
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In our production halls, the line for 2-chloro-5-nitro-3-(trifluoromethyl)pyridine reflects the attention to detail and process development our teams have honed over the years. From sourcing raw materials to the final stages of purification, our batches show what it means to control every step under the plant roof. The chemistry behind this compound pulls on not only reliable chloro and nitro substitutions, but brings another layer of complexity with the trifluoromethyl group at the 3-position. Operators and engineers keep a grip on every variable. We monitor temperature ramp rates, solvent quality, filtration times, and the dryness of intermediates. If there’s one thing years of manufacturing have taught us, consistency doesn’t happen by accident. Yields improve by tracking every detail and fixing the ones that matter most at scale.
Factory output of 2-chloro-5-nitro-3-(trifluoromethyl)pyridine usually centers on crystalline powders, the preferred form for technical and synthetic work. Chemists, especially those focused on scale or research, have noted that batch-to-batch variation throws off downstream reactions. With this compound, we focus on keeping the active assay above 99%, minimizing trace byproducts, and managing residual solvents below strict analytical targets. This isn’t just for paperwork or audits. When customers come back with feedback, the recurring theme involves reliability. Consistent color, particle size, and purity carry real weight with our longtime clients.
Every pyridine derivative brings its own quirks to storage, handling, and downstream chemistry. With 2-chloro-5-nitro-3-(trifluoromethyl)pyridine, certain physical characteristics stand out. The crystalline solid tends to pack densely and resists clumping, unlike some more hygroscopic nitro aromatics. Shelf life is another strong point, as the trifluoromethyl anchor lends oxidative stability and doesn’t hydrolyze under ordinary lab humidity. Chemical manufacturers who work with several related intermediates notice that this compound tolerates a broader range of storage conditions. It resists yellowing or decomposition better than unsubstituted or mono-substituted analogs.
Not all customers require this level of stability. Still, for those scaling reactions up from the lab to pilot reactor, avoiding unpredictable impurities at later stages spares headaches and extra purification steps. This is especially relevant once downstream processes involve more sensitive coupling partners or catalytic systems prone to side reactions. The value in this chemical’s profile reveals itself through its resilience against unwanted degradation, even when transferred across plant sections or between warehouses.
The landscape of fine chemical production moves to the rhythm of demand in pharma, agrochemicals, and specialty materials. Our material has earned its place as a trusted building block in developing active compounds, especially in the early stages of synthesis where the nitro, chloro, and trifluoromethyl groups serve as vital handles for further modification.
Customers working in pharmaceutical research reach for 2-chloro-5-nitro-3-(trifluoromethyl)pyridine as a core intermediate in the creation of certain heterocyclic scaffolds destined for advanced medicinal chemistry. The electron-deficient ring system stands out, acting as both a strategic point for nucleophilic displacement and, through the nitro group, a launching site for reductions and cross-coupling. Synthetic chemists often favor these trifluoromethylated pyridines because the CF3 moiety can boost bioavailability or metabolic stability in lead compounds. The nitro group doubles as both a synthetic precursor and a functional group that shifts reactivity in key coupling steps.
Outside pharma, teams in agrochemicals produce broad-spectrum crop protectants, leveraging the resilience and functional versatility this molecule delivers. Saving process steps and reducing purification needs has material impact when working at hundreds or thousands of kilograms. Our operators field questions around every nuance of scale, including solvent recovery, dust formation, and even the way the solid suspends during slurrying. The practical realities mean we adapt packaging and logistics to shifting material properties, responding not to abstract theoretical needs, but to calls and emails from process chemists working in plants like ours.
Decades of manufacturing these substituted pyridines reinforce one lesson above all: preparation for storage, handling, and compatibility makes or breaks long-term supply relationships. Our teams learned early on from cleaning out bins and repairing conveyor lines. Dust control and proper container selection prevent material loss and cross-contamination. This compound holds together better than some less robust nitro-aromatics, greatly reducing waste from caking and sticking. Regular feedback from plant partners shapes our logistics. For example, insulating drums during seasonal swings preserves the compound’s dry, free-flowing character—even after months on pallets.
We resist the urge to over-package, because our partners have made clear that excessive barriers slow down their own production floors and create extra waste. Instead, we favor industrial sacks with antistatic liners for medium to large users, and tight-head drums for situations requiring longer distance transport. Our colleagues in shipping monitor for physical integrity at every transfer point. By tracking real production issues—spillage rates, container compatibility, on-the-ground storage failures—we keep refining both product and packaging, guided less by theory than by what our plant teams and partners actually face day by day.
Process chemists often ask why they should pick 2-chloro-5-nitro-3-(trifluoromethyl)pyridine over another substituted pyridine for novel synthesis programs. The answer lies in lived factory experience rather than shiny product catalogs. Once scaling up from flask to kilo or ton, small differences turn big. This pyridine stands firm through a range of reaction conditions that usually stress competing analogs.
For nucleophilic aromatic substitution, the electron-withdrawing trifluoromethyl and nitro groups both activate the ring toward displacement, allowing substitution at the chloro position using milder reagents and lower temperatures. Teams pushing for efficiency notice higher selectivity and fewer byproduct complications compared to less finely tuned building blocks. When companies substitute a methyl for the trifluoromethyl, or swap out the nitro for another electron sink, they see longer reaction times, reduced yields, or greater cleaning needs.
Downstream process folks have also highlighted another distinction: waste generation during workup. Our batches of this product create less tar formation because minor impurities and thermal instability get controlled at the production step, not shoved downstream for someone else to solve. Competing products sometimes sport a comparable specification on paper, but in real reactors, the devil lives in the details. Plant managers share how our product cuts the cycle time on reaction and filtration, feeding directly into cost and energy savings with every new lot.
From our earliest days scaling up nitroaromatic production, we witnessed firsthand the crossroads between efficiency and safety. The design of the nitro-chloro-pyridine line took in lessons from old generation plants with too little ventilation or dust control. Now, we deploy dust extraction at transfer points, vigilance around potential static discharge during fine solid handling, and closed transfer systems whenever the risk of inhalation or combustion rises.
Weekly checks on temperature excursions, regular audits for pressure build-up, and real-time sensor feedback keep safety up front, not as an afterthought. Regulations governing nitro aromatics change fast, sometimes yearly, spurred by worker health research or new downstream application guidelines. We invest time and resources in compliance not only because auditors demand it, but because operators and supervisors deserve confidence that their daily work meets the highest bar, without question or compromise.
Much of what guides our improvements comes from listening. We get daily calls from chemists at research companies, engineers in intermediate plants, and specialty formulators. Feedback piles up around the properties that most affect workflows. One month, two customers mention dusting during weighing—our process engineers look at the milling and blending units, adjust screen specifications, and test granulation tweaks until the issue subsides. The next, queries come in about extraction yields. We work up a focused QC study and pass the data straight to those on the synthesis front line.
Modifications to production runs emerge from these field insights. That means batch notes, not just lab data, play a central role. Example: when rumors of an off-odor batch circulate, we track raw materials and solvents, revisit supplier audits, and sample drums across the warehouse. Collaborative partnerships don’t run on polite silence. Our technical team reaches out until users’ actual hurdles become a resource for driving the factory forward. Where new chemical pathways emerge, or analytical hurdles appear, we feed those lessons back into the plant’s daily run plan.
As production volumes of complex pyridines climbed, we faced growing scrutiny around effluent and emissions. Our on-site waste treatment facility evolved from a basic filtration operation to a more advanced multiphase treatment line—neutralizing acids, precipitating heavy metals, and separating even persistent traces of fluorinated organic residues. Real benchmarks for environmental stewardship rise each year, and chemical manufacturing can’t treat them as distant threats.
Plants like ours run pilot tests for alternate process solvents, flue gas scrubbing, and improved rinse water recycling. Every gram of product extracted from aqueous or solvent waste feeds into plant efficiency as much as it does local ecosystem health. We track and report these figures to regulators and community boards, because skepticism only fades with real numbers and lasting performance. Over the past decade, runoff and emissions complaints from neighboring districts dwindled. Our operators walk the perimeter after storms, take real samples, and share the findings, not for show but because plant legacy depends on earned trust.
Every manufacturer faces moments when raw material shipments run late or global logistics throw up unforeseen hurdles. From hail-damaged rail lines to shortages of high-purity starting reagents, the supply of 2-chloro-5-nitro-3-(trifluoromethyl)pyridine has faced its share of near-misses. Maintaining partnerships up and down the chain grows vital, not only for sales, but so the flow of materials fits production needs without overwhelming storage or letting idle time eat away at margins.
Forecasting and flexible contracts with select raw material suppliers buffer the bumps. Site managers review lead time and freight risk with each new shipment, adjusting batch timing so downtime shrinks to the margins. Investors sometimes ask whether digital management tools or buzzword-heavy supply tracking can solve it all—experience shows only site-level foresight and constant communication beat unplanned stoppages. Every time logistics ease, process reliability returns, everyone up and down the chain sleeps a bit better at night.
Youth bring technical skills, but expertise passes down from hands-on training, from engineers who troubleshoot crystallizers on night shift or scale up a new batch at dawn. Our plant keeps one eye on automation and one on building judgment through cross-department mentoring. New hires spend weeks tracking powders and learning the subtleties of running nitroaromatic lines, dosing solvents, and chasing impurities through column and HPLC.
As digital tools improve yield and plant safety, the next leap comes not from machines alone, but from training staff who can spot early signs of batch deviation, material fouling, or off-normal product appearance. Senior techs know the drift in color, small changes in odor, or subtle loss of crystallinity spell future trouble in downstream chemistry. Our crews swap tips not in training room lectures but over the lines, trading best batches for toughest fixes, in a plant culture built on passing skill as much as passing product.
Academic breakthroughs around pyridine chemistry only prove their mettle once scaled. We’ve seen dozens of promising new derivatives falter at the pilot stage, where solvent incompatibility, thermal instability, or tricky byproduct profiles expose what bench experiments could gloss over. Our R&D offices work with process teams to de-risk that step, by feeding real plant data back into design thinking.
Collaborations with synthetic chemists at partner research institutions often begin by sharing practical notes: how solids filter in aged columns, whether off gases spike under high stirring, how to reformulate or swap solvents for better environmental compliance. Many times, a process that glides along in a hood stalls under full plant oxygen or kiln-dried air. Open exchange lets us reach solutions faster, cutting learning cycles and reducing scrap, right at the intersection where science meets the production line.
This isn’t a generic chemical that rolls off one plant and lands in the lap of every downstream user without adaptation. Whether used as a pharma intermediate, a crop protection precursor, or a building block in specialty materials, 2-chloro-5-nitro-3-(trifluoromethyl)pyridine puts production expertise, operator vigilance, and user feedback to the real test.
Over the years, we saw each batch as an exchange. Not just a product on a manifest, but the sum of hands-on learning, materials science, regulatory stewardship, and plant floor urgency. Consistency, not just purity, sets apart a well-run process—and product reliability builds not just in titration columns, but in the back-and-forth between the teams who make it and those who use it. Experience doesn’t only mark the company’s past; it’s the ongoing record of how each new demand gets absorbed and improved on.
For us, every incoming inquiry about this pyridine derivative closes the distance between manufacturing and application. As new uses and challenges arise, the cycle of production, response, and continuous feedback keeps the compound on course—not just in documentation, but in real-world laboratories, factories, and fields where it performs where it counts.
