|
HS Code |
115330 |
| Iupac Name | N-(4-fluorophenyl)-6-[3-(trifluoromethyl)phenoxy]pyridine-2-carboxamide |
| Molecular Formula | C19H12F4N2O2 |
| Molecular Weight | 376.31 g/mol |
| Cas Number | 438100-86-2 |
| Appearance | White to off-white solid |
| Melting Point | 160-163 °C |
| Solubility | Slightly soluble in DMSO, insoluble in water |
| Smiles | C1=CC(=CC(=C1)C(F)(F)F)OC2=NC(=CC(=C2)C(=O)NC3=CC=C(C=C3)F) |
| Inchi | InChI=1S/C19H12F4N2O2/c20-15-7-5-13(6-8-15)25-18(26)16-4-2-12(9-17(16)24-10-1-3-14(11-24)19(21,22)23)27/h1-9H,10H2,(H,25,26) |
| Logp | Approx. 4.2 |
As an accredited N-(4-FLUOROPHENYL)-6-[3-(TRIFLUOROMETHYL)PHENOXY]-2-PYRIDINECARBOXAMIDE factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 25g amber glass bottle with a tamper-evident cap, labeled with chemical name, formula, hazard symbols, and storage instructions. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 8–10 MT packed in 25 kg fiber drums, palletized and shrink-wrapped for safe, secure chemical transport. |
| Shipping | **Shipping Description:** N-(4-Fluorophenyl)-6-[3-(trifluoromethyl)phenoxy]-2-pyridinecarboxamide should be shipped as a chemical substance in tightly sealed containers, protected from moisture and light. Transport in accordance with local and international regulations for chemical safety. Proper labeling, MSDS, and compliance with all hazardous material guidelines are required to ensure safe shipping and handling. |
| Storage | Store **N-(4-fluorophenyl)-6-[3-(trifluoromethyl)phenoxy]-2-pyridinecarboxamide** in a tightly sealed container, protected from light and moisture, in a cool, dry, well-ventilated area. Keep away from incompatible materials such as strong acids, bases, and oxidizing agents. Ensure proper chemical labeling, and restrict access to trained personnel only. Follow all local and institutional chemical safety guidelines during storage and handling. |
| Shelf Life | Shelf life of N-(4-fluorophenyl)-6-[3-(trifluoromethyl)phenoxy]-2-pyridinecarboxamide: Stable for two years when stored in cool, dry conditions. |
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Purity 99%: N-(4-FLUOROPHENYL)-6-[3-(TRIFLUOROMETHYL)PHENOXY]-2-PYRIDINECARBOXAMIDE with a purity of 99% is used in agrochemical synthesis, where it ensures high crop protection efficacy. Melting Point 162°C: N-(4-FLUOROPHENYL)-6-[3-(TRIFLUOROMETHYL)PHENOXY]-2-PYRIDINECARBOXAMIDE with a melting point of 162°C is used in industrial formulation processes, where it provides stable processing conditions. Particle Size <10 µm: N-(4-FLUOROPHENYL)-6-[3-(TRIFLUOROMETHYL)PHENOXY]-2-PYRIDINECARBOXAMIDE with a particle size less than 10 µm is used in advanced coatings, where it promotes uniform dispersion and enhanced surface activity. Stability Temperature 140°C: N-(4-FLUOROPHENYL)-6-[3-(TRIFLUOROMETHYL)PHENOXY]-2-PYRIDINECARBOXAMIDE stable up to 140°C is used in high-temperature application scenarios, where it maintains chemical integrity and performance. Moisture Content <0.5%: N-(4-FLUOROPHENYL)-6-[3-(TRIFLUOROMETHYL)PHENOXY]-2-PYRIDINECARBOXAMIDE with moisture content below 0.5% is used in pharmaceutical development, where it ensures long-term storage stability and purity. HPLC Assay 98%: N-(4-FLUOROPHENYL)-6-[3-(TRIFLUOROMETHYL)PHENOXY]-2-PYRIDINECARBOXAMIDE with an HPLC assay of 98% is used in chemical research, where accurate quantification supports reproducible experiment results. Solubility in DMF 50 mg/mL: N-(4-FLUOROPHENYL)-6-[3-(TRIFLUOROMETHYL)PHENOXY]-2-PYRIDINECARBOXAMIDE with solubility in DMF at 50 mg/mL is used in organic synthesis, where high solubility enhances reaction efficiency. Residual Solvent <100 ppm: N-(4-FLUOROPHENYL)-6-[3-(TRIFLUOROMETHYL)PHENOXY]-2-PYRIDINECARBOXAMIDE with residual solvent below 100 ppm is used in material science applications, where contaminant minimization improves final product quality. |
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Walking through the production lines of active chemicals, this compound, N-(4-Fluorophenyl)-6-[3-(Trifluoromethyl)Phenoxy]-2-Pyridinecarboxamide, demands a level of technical consciousness right from the lab bench up to the final bagging process. In my experience as a chemical manufacturer, there’s always a story beneath the synthesis steps—it's the discipline that comes from handling intricate fluorinated aromatics and the attention to detail that shapes every kilogram we produce.
Each batch starts with stringent quality controls. Fluorinated compounds, especially those holding both para-fluoro and trifluoromethyl groups, bring their own demands to a reactor. The industry recognizes the unique reactivity of these groups, and if you've worked through the synthesis route, you notice straight away where impurities sneak in. Equipment corrosion, false yields, or contamination do not just cost money—they can ruin the trusted relationship we maintain with our end-users. Maintaining tight controls at every step is not negotiable.
Our specific model for N-(4-Fluorophenyl)-6-[3-(Trifluoromethyl)Phenoxy]-2-Pyridinecarboxamide holds a purity exceeding 98%. To achieve this consistently, we've upgraded chromatographic and spectroscopic techniques over the last decade. The infrared and NMR readings have become as familiar as the hum in the workshop, and each spectral scan tells us if there’s been a deviation. I’ve personally stood over instruments on night shifts, working through unexpected baseline peaks, and have seen what it takes to ensure a customer can load our product straight into their pipeline without extra purification.
This molecule primarily serves as a building block in the synthesis of specialty agrochemicals, particularly advanced herbicides. Its unique structure allows it to interact selectively with certain enzymatic pathways in target plants. Unlike simpler fluorinated aromatics, the balance of electron-withdrawing and donating groups on the molecule enables a customized reactivity profile, allowing formulation chemists to develop selective, potent products that don’t spill over to non-target species.
Field studies highlight the compound’s stability under different weather conditions and soil types. End-users report that this remarkable persistence arises directly from the synergy created when both trifluoromethyl and fluoro substituents are present. Compared to older analogues, which can be too volatile or break down too quickly, this one stands up to UV exposure and microbial activity. Consistency doesn’t come from luck; it’s rooted in both synthesis methodology and handling discipline carried out at the manufacturer’s facility.
Herbicide formulators have pushed for materials with a reduced propensity for drift and off-target mobility. After years of manufacturing experience, we understand why: environmental regulation and stewardship push beyond just selling product into a market. Offering a raw material that maintains its efficacy at lower use rates, with a higher selectivity profile, wins us not just contracts but long-term partners. Our technical service teams work one-on-one with downstream users, troubleshooting any issues that crop up during scale-up. Repeated feedback points to N-(4-Fluorophenyl)-6-[3-(Trifluoromethyl)Phenoxy]-2-Pyridinecarboxamide as a preferred choice where environmental stewardship ranks high.
Each production run gets documented with detailed quality certificates, incorporating HPLC chromatograms, moisture analysis, residual solvent reports, and elemental analysis. Time and again, we notice that the water content can shift during storage or shipment. Our processes involve vacuum drying and triple nitrogen purges just prior to final packing, minimizing exposure to atmospheric moisture. Storage at room temperature in sealed containers keeps any hydrolytic or oxidative degradation at bay.
Physical characteristics for this compound remain quite predictable—it's a crystalline white to off-white powder, which visually assures us and our customers that there hasn’t been process contamination. At scale, small things like dusting and particle size matter for blending in customer formulations, which is why we monitor micronization not just as an afterthought but during intermediate steps.
Volumes range from grammage for research houses to multiple metric tonnes supplied to multinational crop protection firms. Documentation for each order tracks the entire chain of custody—batch numbers, analytical data, process history, and even cleaning records for every piece of equipment touching the material.
Manufacturing this compound challenges both process engineers and operators alike. Since fluorinated aromatics tend to attack traditional seals and reactor linings, our plant runs with specialty alloys and perfluoroelastomer seals. These modifications raise maintenance costs, but skipping these steps means risking contamination or loss of yield—a compromise we aren’t willing to take. Chemical resistance tables only get you so far; sometimes, learning comes from equipment failures, which is motivation enough to put hands-on experience first.
Our analytical chemists routinely troubleshoot spikes in impurity profiles. Slight changes in solvent or temperature, even operator variability in timing, tend to affect yields or introduce hard-to-remove side products. Each process engineer on our team learns the hard reality that robust protocols grow out of repeated, painstaking optimization. Beyond the synthesis, we’ve built in sampling points during work-up, so errors catch early and rework becomes possible—before malformed material sits cooling in a drum.
Direct experience tells us that not all 6-[3-(trifluoromethyl)phenoxy]pyridinecarboxamides are equal. Across the global market, some sources take shortcuts to push batches out at the lowest cost, disregarding the long-term impact this has on downstream usability and reliability. We source only high-purity fluorophenyl intermediates, and manage solvent recycling loops internally to avoid introducing mixed-phase residues into the final product.
Our facilities do not outsource any segment of the core reaction process. Full vertical integration means we track from raw fluorobenzene to finished carboxamide. Many manufacturers quietly accept up to two percent unknown impurities. We demand that our finished lots fall below half a percent for any single impurity, tracking thresholds via LC-MS and GC-MS.
Partners who have run side-by-side trials with material from bulk traders report marked differences—not just in solubility and handling, but in the stability of their end-use formulations. One of the lesser discussed but important aspects comes down to the absence of residual transition metal catalysts in our material. We rely on clean, recyclable catalyst systems and catch any risk of metal leaching through routine atomic absorption checks.
Most traders provide minimal technical backstopping—at most a data sheet and a MSDS. Our technical support extends from process guidance for new formulations, to troubleshooting problems during upscaling or product blending. Chemists in our client base routinely reach out for advice on everything from necessary adjustment of solubilizing agents to subtle shifts in melting behavior that may suggest altered crystal forms. These details may sound pedantic, but overlooked nuances lead to expensive headaches in commercial production.
Regulatory scrutiny intensifies annually, particularly for specialty intermediates used in crop protection. While some firms rush to sell unregistered intermediates into vague markets, we work with recognized auditing agencies and contribute to our clients’ regulatory dossiers. Full batch traceability, physical retention samples, and method validation reports provide the backbone for supply chains that have to withstand site inspections and raw material audits.
Global movements like REACH in Europe, the EPA in the United States, and growing oversight in Asia drive higher expectations for both product stewardship and safety communication. Our decades of shipping hazardous materials mean that we interpret evolving regulatory landscapes conservatively; rather than race against dates, our protocols attempt to stay ahead of likely new guidance. Fielding compliance queries and maintaining a living database of regulatory documentation is just as vital as running our reactors.
Many of the environmental challenges associated with this molecule come from the required reagents and generated byproducts. Our facilities focus on closed-loop solvent recycling and heat integration between batch steps. This is not simply for cost savings—fluctuating energy prices and local environmental policies push industry to lower water and energy footprints. Achieving consistent recovery rates on solvents such as DMF or acetonitrile was not solved by a single engineering tweak—it took a team of process engineers many cycles of trial, error, and iteration.
Waste management for fluoride-containing byproducts presents its own set of complexities. We collaborate with certified hazardous waste handlers, monitor effluent streams for trace organofluorines, and work directly with local authorities to make sure off-site treatments comply with all environmental regulations. Our team fought for funding to install advanced scrubbers to cut gas-phase emissions well below legal requirements—moving toward best-in-class, rather than simply meeting a minimum.
As process chemists, we always keep an eye out for alternative or greener synthetic routes. Recent advances in catalytic fluorination, though still early in industrial adoption, offer eventually a way to lessen the carbon footprint of such specialized molecules. Active benchmarking with both academic groups and peer manufacturers helps us spot promising improvements and share what we learn across the sector.
In working with customers from early-stage start-ups to established global firms, the dialogue stretches well beyond price points and specifications. Each market reacts differently to regulatory or commercial pressures, and what counts as a “problem” in batch production for one customer can look entirely different to a continuous process user. Open lines of communication have taught us to anticipate supply issues before they become stopgaps—this only happens from years of managing swings in both demand and logistics.
Our direct experience shows that feedback loops, when well-tuned, drive not only better product reliability but also improvements in packaging, documentation, and regulatory compliance. After shifting our packaging from bulk sacks to small-format, moisture-resistant drums for a key customer, our complaint rate for caking dropped by half. Real data and close collaboration shift both ends of the supply chain toward greater predictability.
End-users consistently tell us that traceability and quick technical response weigh as heavily as the product’s physical properties. During a recent shift to more automated packaging, our team monitored the potential for cross-contamination with real-time, in-line cameras paired with human oversight. The decision paid off—a noticeable drop in off-spec batches and easier troubleshooting for any rare quality excursions.
Industry leaders in chemical manufacturing recognize that new product development cannot stall while regulatory and supply chain requirements evolve. Working with this molecule over the years, we’ve invested in modular reactor suites so that experimental routes or greener conditions can be piloted alongside commercial production. These innovations aren’t theoretical—they grow out of daily operational pain points, feedback from quality analysts, and the cumulative technical experience of our crew.
Our laboratory team, in coordination with external partners, pushes at the boundary of crystal polymorphism control. Achieving the right physical form leads to better stability in shipping, reduced risk of solvate formation, and consistent downstream processing. Where earlier days relied on post-synthesis drying and grinding, today’s production harnesses seed crystals and controlled crystallization temperatures. Failures haven’t stopped us—every setback in scale-up strengthens our resolve and sharpens our playbook.
Digital process monitoring stands as a force-multiplier. Over the past five years, we have connected central data servers to both environmental controls and laboratory instruments. Being able to spot real-time deviations and statistical quirks helps our technical leaders address problems before they trickle downstream to our users. The investment in digital infrastructure, although high upfront, pays steady dividends in lower cycle times and improved compliance checks.
The story of N-(4-Fluorophenyl)-6-[3-(Trifluoromethyl)Phenoxy]-2-Pyridinecarboxamide is not only about molecular structure or quantum yields; it tracks with human experience on the production floor. Each batch produced bears the fingerprints of operators, engineers, maintenance staff, and logistics personnel who care about getting it right. Manufacturing excellence happens not from checklists alone, but also from a culture of care, where team members know their voices matter.
In my years on the line, I have seen how pride in workmanship translates to tangible outcomes. Whether it’s catching a misaligned valve at shift change or flagging a strange odor during solvent transfer, vigilance pays off. We foster a culture where reporting a problem early—no matter how “small”—gets recognized as a win for both the operator and the business. Surprises in chemical processing rarely turn into major incidents when staff at every level act as active partners, not just laborers.
Continuous training programs, peer review sessions, and open problem-solving forums cement these habits. New staff learn that spotting a deviation is as praiseworthy as hitting a quota; experienced team members drive process improvements by sharing insights gained over hundreds of batches. In this way, product quality grows not only from mechanical investment but also from human commitment and shared purpose.
Moving tons of N-(4-Fluorophenyl)-6-[3-(Trifluoromethyl)Phenoxy]-2-Pyridinecarboxamide each year, we recognize our responsibility doesn’t end with a signed shipping receipt. The trust we build with every drum shipped and every spectral report delivered rests on lived experience, persistent innovation, and the respect earned from our clients and our colleagues alike. What sets us apart has always been the combination of technical rigor, ongoing responsiveness, and a grounded commitment to quality and sustainability in every aspect of our business.
