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HS Code |
194977 |
| Product Name | ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE |
| Molecular Formula | C17H10ClF3N2O3 |
| Molecular Weight | 398.72 g/mol |
| Appearance | Solid |
| Color | Off-white to pale yellow |
| Solubility | Slightly soluble in organic solvents (e.g., DMSO, DMF) |
| Storage Conditions | Store at 2-8°C, protect from light and moisture |
| Purity | Typically >98% |
| Structure Type | Heterocyclic aromatic ester |
| Smiles | CCOC(=O)C1=CN=C2C(=C1O)N(C3=C(C=C(C=C3F)F)Cl)C=CC2F |
| Functional Groups | Ester, halogenated aromatic, pyridine derivative |
| Uses | Pharmaceutical intermediate or chemical research |
As an accredited ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Sealed amber glass bottle containing 25 grams, labeled with chemical name, purity, CAS number, hazard warnings, and manufacturer details. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 10–12 metric tons packed in 25 kg UN-approved fiber drums with inner double-layer PE bags (palletized). |
| Shipping | This chemical should be shipped in tightly sealed containers, protected from light and moisture, and under room temperature unless otherwise specified. It must be packaged according to local, national, and international hazardous goods regulations. Ensure clearly labeled containers, include safety data sheets, and use appropriate cushioning to prevent leaks or breakage during transit. |
| Storage | Store ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE in a tightly sealed container, away from direct sunlight and moisture, in a cool, dry, and well-ventilated area. Ensure it is kept away from incompatible substances, sources of ignition, and oxidizing agents. Use appropriate personal protective equipment when handling, and clearly label the storage area for chemical safety compliance. |
| Shelf Life | The shelf life of ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE is typically 2 years when stored properly. |
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Purity 99.5%: ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE with 99.5% purity is used in pharmaceutical intermediate synthesis, where it ensures high yield and product consistency. Melting Point 182°C: ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE with a melting point of 182°C is used in high-temperature manufacturing processes, where it promotes thermal stability during formulation. Molecular Weight 394.72 g/mol: ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE of 394.72 g/mol is used in analytical research, where it allows precise quantification and reproducibility. Stability Temperature 120°C: ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE with a stability temperature of 120°C is used in chemical storage environments, where it prevents product degradation. Particle Size D90 < 50 μm: ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE with particle size D90 < 50 μm is used in formulation development, where it improves blend uniformity and dissolution rate. Moisture Content < 0.2%: ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE with moisture content below 0.2% is used in moisture-sensitive reactions, where it enhances product stability and reduces hydrolysis risk. Residual Solvent < 50 ppm: ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE with residual solvent level under 50 ppm is used in regulated pharmaceutical manufacturing, where it meets safety and compliance standards. |
Competitive ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE prices that fit your budget—flexible terms and customized quotes for every order.
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In the world of chemical manufacture, every molecule counts. Over the years, our work with key intermediates for pharmaceutical and agrochemical industries has pushed us toward reliable and cost-efficient synthetic routes. Significant updates in organic fluorine chemistry impact how raw materials perform at scale, influence the achievable purity, and set benchmarks for process efficiency. ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE represents the intersection of those advancements. Our R&D teams developed and refined synthesis for this molecule through hundreds of iterative batches, focusing on safety, yield, and environmental controls.
Intermediate manufacturers seldom gain visibility in final products, but the quality of input defines the possibilities down the line. In our synthesis of this compound, each batch goes through a crystallization stage to optimize for particle size and suppress formation of hard-to-remove side products. The molecular architecture—a difluorinated phenyl ring, reinforced with chlorine and fluorine substitutions on the pyridopyridine system—delivers not only reactivity in targeted cross-couplings but also high thermal stability.
Since this intermediate often enters complex synthesis routes for crop protection and next-generation pharmaceuticals, we monitor organo-halide purity and manage trace impurities from early steps. Our in-process controls don’t rely solely on HPLC snapshots—a fully integrated NMR and MS profile backs our judgments about batch acceptability. Learning from multiple campaigns, we adjusted solvation and workup parameters to reduce residual moisture and cut batch-to-batch variation in physical form, stripping out pain points for technicians in downstream plants who require predictable solubility and filtration behavior.
Comparing products with similar chemical scaffolds on price or CAS number tells only half the story. Many suppliers trade this intermediate as a commodity, leaving users to tighten process specs upstream or invest time in laborious reprocessing. Our approach looks at the entire downstream sequence faced by synthetic chemists. Thanks to robust process mapping, our batches reach demonstrated impurity profiles well below 0.1 percent for common halogenated byproducts. Instead of relying on generic filtration, we employ staged isolation, which strips persistent contaminants that complicate scale-up in oxidative or catalytic applications.
Practically, this means users making active ingredients for emerging agrochemicals or advanced pharma molecules open the drum to a product ready for direct dissolution and charging to reactors. The time our manufacturing staff spent on granular process development translates to fewer deviations for our clients and reduced solvent demand in their workup. We ship in a stabilized crystalline form, which supports safer transfer, storage, and handling, eliminating excessive dusting—a feature that plant operators appreciate during drum-to-vessel operations.
We stamp each consignment with a batch certificate grounded in real, observed process control data. Analytical methods for this compound evolved around high-throughput screening, not off-the-shelf protocols. Long before dispatch, our analysts verify every shipment by NMR, LC-MS, and GC to confirm molecular identity, quantitative purity, and absence of process-introduced artifacts. We test for halide, residual solvent, and elemental levels to anticipate and resolve feedstock risks long before they propagate into costly GMP or field-level rejections.
The physical form stands out—crystalline, non-hygroscopic, shelf-stable across typical warehouse conditions—so shipment and storage pose minimal risk for customers in regions with variable humidity or temperature control. Moisture content typically lands below 0.05 percent. For solvents like DCM, THF, or MeOH, users won’t find persistent residues. In every kilo of ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE, there’s a direct line to our plant operators’ focus on repeatability and recoverability.
Raw materials often fail to live up to promise under scale-up pressure. We’ve seen project delays caused by off-spec batches from generic vendors—repeated filtrations or chromatography, troubleshooting product that cakes or forms colloidal suspensions, or spending unscheduled hours removing trace halides that upset catalyst screens. For this intermediate, we commit to supply a physically robust, chemically reliable input, shaped by production experience in vessels ranging from 50 kg to multi-ton scale. We calibrate every synthetic run to anticipate how the product will perform beyond our gates.
Our clients range from active ingredient producers to research teams at pharma innovators. Many came to us after wasting effort reformulating their own purification steps. In direct feedback, they report time saved in reactor charging, faster dissolutions in both organic and aqueous systems, and sharper endpoints in stepwise coupling or cyclization reactions. The ability to move from arrival of raw material to productive synthesis in minimal time makes the difference in project momentum, especially where development timelines are tight.
Our technical support team hears it often—batch failures downstream rarely stem from active process errors or equipment breakdowns, but from inputs that don’t behave as predicted. For those deploying ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE into new synthetic routes for agricultural chemistry, the molecule’s reactivity governs installation of downstream pharmacophores, while the halogenated structure influences selectivity in oxidative functionalizations.
On the pharma side, it often features as a penultimate intermediate—constructed for its ability to accept substitutions or enter palladium-catalyzed reactions cleanly. The tight impurity control means clients spend less time adapting process safety clearance runs, regulatory filings, or running redundant isocratic purification. Whether it’s an agrochemical active ingredient or a potential API building block, the dependability in crystallinity and solvation profile directly impacts routine yields and throughput.
Industry conversations turn frequently to sustainable production practices, not as an afterthought, but as a matter of survival in regulated markets. In working with this compound, our teams substituted traditional hazardous halogenation agents, favoring routes with less waste and improved worker safety. Automated solvent recycling and closed transfer systems limit emissions in our plants. We’ve redesigned our purification stages to minimize persistent organic pollutant risks and non-degradable residues.
Suppliers who embrace mere minimum compliance risk supply chain shocks—regulatory holds, excessive batch rework, or delayed qualification by end users. Our engagement with internationally recognized sustainability benchmarks affects not only our operational footprint, but also the long-term acceptability of our material in global markets. By documenting process changes, sharing analytical data, and maintaining open channels with regulators, we give our customers the ability to pass audits and regulatory queries with confidence.
Not all chemical intermediates carrying this molecular designation perform equally when put to work. Through hands-on synthesis, we recognized subtle differences between similar-looking products—some suppliers accept higher levels of fluoroaryl or unreacted halide contaminants in the batch, which later manifest as ghost peaks or unexpected byproducts. We reject those approaches. In-house process control means our product is free from problematic process-derived impurities that can derail a coupling or prompt a failed QA result just before product release.
Another point of contrast: packaging and on-site usability. We ship in drums or lined fiber kegs that facilitate safe, direct transfer to process vessels. Feedback loops from customer pilot plants have shaped packaging—no bagging or secondary repackaging steps, reducing operator exposure risk and downstream waste. The absence of fines or adhesive residues during dispensing cuts loss and contamination for our clients, making every kilo delivered functionally available for their reactions.
With emphasis on detailed particle size control, our batches dissolve readily and disperse smoothly—plant chemists don’t battle clumps, caking, or prolonged agitation. This focus on physical handling has been built into our process since early scale-up trials, at the urging of users who struggled with less robust material elsewhere. Our supply chain rigor extends to batch documentation, regulatory support, and direct access to R&D chemists who can respond to technical hurdles in real time.
Anyone working up a scale synthesis knows that paper specs fade quickly if material performance slips. The difference between a product that flows as intended and a recalcitrant, sticky, or impure intermediate can mean the loss of weeks or months. Our reputation rests on repeatable, transparent results: not just certificates of analysis, but validation packages shared with clients, who apply not only their in-house tests but also their practical process knowledge.
Our customer partnerships go beyond single transactions. Each complaint or insight triggers an internal review: Did a drum suffer during shipment? Did unexpected impurities crop up in a given synthesis? We treat feedback as a prompt to adjust, not an annoyance. Changes in global or local regulations—restrictions on solvents, limits on halogen or heavy metal residue—feed directly into our control logic. This responsiveness has earned us long-term customers who measure supply chain resilience and technical congruence, instead of chasing one-off price reductions.
Chemical manufacturing never unfolds as a closed book. We engineer every stage to reduce the downstream need for reprocessing or intervention—from choice of reactants, through final drying and packaging. Rarely does a week pass without someone in our plant identifying a tweak or improvement—a filtration adjustment that improves clarity, a pH hold that maintains product form, or an updated cleaning protocol that prevents cross-contamination. These observations find their way into process documentation, so future batches embody lessons learned.
By handling every step in-house—no unvetted third-party processing, no sourcing intermediates from uncontrolled sources—we maintain end-to-end visibility over quality, reliability, and compliance. When new customers engage us, they learn quickly that our focus is on more than selling drums—it’s on advanced process partnership. The weight of accumulated experience, routine process audits, and continuous operator education delivers a consistency that never comes out of an anonymous supply network.
Regulatory agencies frequently update guidance on fluorinated compounds and organohalides, pressing manufacturers to adapt or risk obsolescence. Rather than reactively scrambling to tweak specs, our R&D and process chemistry teams remain embedded in industry and academic discussions. Monitoring evolving frameworks from European as well as Asian and North American regulators enables us to anticipate, not chase, compliance. Our supply assurances rest not only on consistent current standards, but on forward-looking process management that considers future regulatory directions.
From new cold-chain or green chemistry standards, to shifts in analytical requirements for genotoxic impurities, we bring those debates into the plant. No step in the manufacturing or analytical process stands still. Operators, chemists, and compliance managers work together to keep process documentation ahead of the regulatory curve. This mindset enables customers who build on our material to advance their own products through development, qualification, and launch, with minimal interruption.
Every successful synthesis campaign stems from thousands of choices by local staff. An operator suggests an improved wash that cuts sodium levels, or a technician recalibrates a filtration endpoint for sharper separation. Each detail—minor or major—feeds into collective know-how, reinforcing strengths and illuminating areas for further fine-tuning. Our commitment to improvement shows in reduced waste, shortened cycle times, and higher first-pass acceptance rates for each batch shipped.
With prolonged customer engagement, we often hear about shifts in their end product formulations or regulatory needs. Instead of passing along responsibility, we work alongside our client process chemists to adapt specs, modify particle sizing, or prequalify analytic standards. The most innovative agrochemical and pharma projects demand this level of involvement, where feedback, revision, and adaptability govern the long-term business relationship—not hollow declarations of alignment with “customer satisfaction.”
No intermediate stands alone in a supply chain. The true test comes under deadline and scale pressure—can the material perform predictably, accommodate shifting regulatory realities, and maintain quality over repeated, high-volume runs? From the earliest R&D trials to late-stage commercial production, our commitment centers on seeing the whole journey: from raw molecular assembly through delivery, and into the realities faced by process chemists operating in factories, not showrooms.
Customers who select our ETHYL 1-(2,4-DIFLUOROPHENYL)-7-CL-6-F-4-O-HYDROPYRIDINO[2,3-B]PYRIDINE-3-CARBOXYLATE invest in depth of experience, controlled process innovation, and the continuous, sometimes unglamorous work needed to anchor cutting-edge chemistry on a foundation of reliable intermediates. The value shows not simply in certificates or paperwork, but in uneventful, successful days in the plant—when the right material comes in, and productive chemistry can follow.
