|
HS Code |
946487 |
| Chemical Name | 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro- |
| Iupac Name | 5-chloro-2-fluoropyridine-3-carbaldehyde |
| Molecular Formula | C6H3ClFNO |
| Cas Number | 850568-85-1 |
| Appearance | Pale yellow to brown solid |
| Boiling Point | No data available |
| Melting Point | No data available |
| Density | No data available |
| Solubility | Soluble in polar organic solvents |
| Smiles | C1=CC(=C(N=C1F)C=O)Cl |
| Pubchem Cid | 12404470 |
As an accredited 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 250g amber glass bottle with tamper-evident cap, labeled with chemical name, hazard warnings, and manufacturer details; foam padding included. |
| Container Loading (20′ FCL) | Packed in 20′ FCL, 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro- is securely contained in approved chemical drums or IBCs. |
| Shipping | 3-Pyridinecarboxaldehyde, 5-chloro-2-fluoro- is shipped in tightly sealed, chemical-resistant containers under ambient conditions. Packaging complies with hazardous materials regulations, protecting against moisture and light. Shipping documentation includes safety data and hazard labels, ensuring safe handling during transport. Specialized carriers qualified for chemical transport are typically used to guarantee regulatory compliance. |
| Storage | 3-Pyridinecarboxaldehyde, 5-chloro-2-fluoro- should be stored in a tightly sealed container, away from light, moisture, and incompatible substances such as strong oxidizing agents. Keep it in a cool, dry, and well-ventilated area, preferably in a chemical storage cabinet. Ensure appropriate labeling and restrict access to trained personnel. Follow all applicable safety guidelines and regulations during storage. |
| Shelf Life | The shelf life of 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro-, is typically 2 years when stored properly in a cool, dry place. |
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Purity 98%: 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro- of purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high-yield and low impurity formation. Melting Point 45°C: 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro- with melting point 45°C is used in solid-phase organic synthesis, where it facilitates controlled crystallization processes. Stability Temperature 80°C: 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro- having stability temperature 80°C is used in catalytic reactions, where it maintains compound integrity under elevated reaction conditions. Molecular Weight 172.54 g/mol: 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro- with molecular weight 172.54 g/mol is used in fine chemical manufacturing, where accurate dosing and stoichiometry are required. Water Content ≤0.2%: 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro- with water content ≤0.2% is used in anhydrous formulations, where it prevents unwanted hydrolysis and maintains product stability. Batch Consistency: 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro- with verified batch consistency is used in multi-step synthetic routes, where reliable reproducibility is critical for scalable processes. Spectral Purity NMR ≥99%: 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro- at spectral purity NMR ≥99% is used in research reagent preparation, where analytical verification supports experimental accuracy. |
Competitive 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro- prices that fit your budget—flexible terms and customized quotes for every order.
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Every shift on the line brings home how much our work shapes the quality of key intermediates like 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro-. This compound shows up in our plant as a slightly pale solution, signaling not only chemical potential but years of hard-earned know-how. The reality is that behind every gram of this compound, the staff has poured over process records, run analysis after analysis, and debated how to squeeze out every trace of impurity. This isn’t about adding another name to a catalog; it’s about repeatable results and reliability across multiple scales.
We don’t talk about “models” in the same way as mass retailers, but batch numbers and inspection slips tell a story of their own. Most often, the batches leaving our reactors sit above 97% assay before final processing, and by the time they hit the drum, we keep moisture well below 0.3%—no theory, just the lab report. Color scale and consistency matter less than molecular truth, since most requests land on our desks from process development teams wanting to scale synthesis without hiccups. Our tools are FTIR, HPLC, and NMR rather than flashy brochures. Any sample we sign off carries its analytical fingerprints, showing the real content and the profile of potential impurities.
Most of the team on the line knows that the true challenge comes not just from making the product, but dialing in those subtle points batch to batch: temperature ramps, acid wash steps, precise distillation cuts. A material with real reproducibility gives downstream users a shot at developing APIs or advanced agrochemical candidates without starting over every time a new drum arrives.
At its core, 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro-, acts as a flexible building block in medicinal chemistry—and it’s no exaggeration calling it versatile. Experienced chemists see a reactive aldehyde tethered to a pyridine, perfect for developing novel scaffolds or fine-tuning activity. The substituents tell a big part of the story: the chlorine dampens electron flow through the ring, the fluorine tunes the reactivity just enough to allow precise transformations. Those factors impact everything from Grignard additions to Wittig reactions.
Lab teams focused on drug candidates value precise starting materials. Minor contaminants complicate analytical work and muddy structure-activity data. Our routines keep up because researchers push deadlines, run full screens, and demand performance they can measure. There’s little room for debate—a bottle straight from the plant needs to deliver the same results every time, or someone’s project timeline slips.
In crop protection, this aldehyde provides a base for incorporating the right functional groups with speed. Synthesis groups swap out protecting groups and design analogues for field tests, measuring uptake and effectiveness season by season. The confidence they need starts in the inspection room: our own in-process controls, solvent rinses, and drying protocols remove ambiguity before these molecules see a research lab or test field.
Plenty of manufacturers make pyridinecarboxaldehydes, but only some can reliably supply this pattern of substitution. Adding both a chloro and a fluoro group—each at defined positions—introduces process complexity many overlook. The route doesn’t favor shortcuts, and suboptimal conditions deliver side reactions or over-oxidation; both act as sources of frustration further down the chain. In our facility, controls start with the sourcing of chlorinated and fluorinated pyridine feedstocks, and continue with monitored oxidative steps where time, temperature, and solvent all mean something. A missed control point often means lost product or reprocessing, neither of which builds trust with long-term customers.
For those used to working with unmodified 3-pyridinecarboxaldehyde or other halogenated derivatives, they notice structural effects right away. The addition of the 5-chloro group moderates reactivity at certain positions on the ring, while the 2-fluoro subtly influences both hydrophobic and steric interactions. Downstream, this translates into either increased selectivity in further reactions or different biological properties altogether. Each run becomes an exercise in balancing the reactivity needed for clean coupling with the stability required for safe handling. Multiple teams work on alternate synthetic sequences to deliver the highest single-pass yield, and we track the data over time to flag process drift long before it hits a customer’s bench. This level of commitment doesn’t show up in glossy pictures, it shows up in repeat orders and steady business through tight market windows.
We’ve also learned that batches meant for pharmaceutical research need a different approach from those targeted at early agrochemical screens. Pharma teams focus on trace-level impurities, especially those structurally related to the parent compound. They demand both analytical data and the ability to trace each step of production. In contrast, agricultural research often pushes for drum-scale quantities and puts a premium on batch-to-batch reproducibility rather than chasing every last trace of an impurity. Meeting these different needs calls for experience both in the lab and on the shop floor.
Our crew works every angle from raw material sourcing to analytical sign-off. Someone always has eyes on weather conditions—humidity in storage spaces can tip a batch above spec for residual water, pushing a timeline days longer. We adapt quickly, running secondary drying or revising vessel use schedules. We’ve seen firsthand how little things, like a pass on glassware or the way a drum is vented, can impact shelf-life or purity.
Knowledge passes down shift by shift. Experienced technicians watch reaction color and phase cut points, their intuition backed by thousands of hours at the bench and in the control room. These aren’t manual skills alone—decisions run through a network of digital logs, in-line spectrometers, and roundtable reviews each time we scale a new campaign.
Supply crunches for halogenated pyridine feedstocks leave scars on everyone’s memory. We’ve built direct relationships with upstream partners and invested in backup supply routes. No marketing copy can smooth over a missed shipment; only real contingency planning and honesty with end-users will. We stay involved with industry groups tracking global chemical flows because production plans hang on knowing which route offers stability over time.
We work out safety and environmental considerations at every stage because regulatory and sustainability demands shape real investment. Our engineers monitor vent scrubbing, neutralization tanks, and hazardous waste codes from each campaign. Chemical manufacturing happens in the real world—violations or short cuts show up in lost licenses, not just fines. Our investment in closed-loop systems and solvent recycling isn’t decoration; it keeps us and our community in business for the long haul.
Customers sometimes run into crystallization issues or unexpected color formation if storage or downstream mixing cuts corners. We’ve redesigned drums and liner packaging to combat cross-contamination and moisture pickup. Years back, an issue with unintended oxidation in transit taught everyone the value of robust packaging and clear end-user guidance. Each repack line operator understands how trace residual acids or solvents can surface as surprises months later, complicating customer QC and holding up projects.
Training doesn’t stop with new hires. Every annual shutdown cycle, we bring in staff from analytical and process teams for review—new techniques in FTIR baseline correction, advances in automated titration, and case studies from last season’s biggest headaches. Real solutions never hinge on a single improvement, they rely on a shared expectation that every department takes pride in zero deviation runs.
To those moving from catalog quantities to commercial needs, scale-up reveals hidden bottlenecks. Small glassware tests never reveal the idiosyncrasies of a 2,000-liter reactor—the way airflow across cooling jackets or sheath heating can create local hot spots. We tackled uneven yield and hotspot degradation through redesigned agitation systems and relentless pilot testing. Fielding calls from scale-up teams means staying honest about what can and can’t be changed overnight. Sometimes a process can use a more conservative temperature ramp or throttle solvent addition to avoid unwanted side reactions. Other times, we advise adding a purification loop or additional hold time before discharge. This back-and-forth isn’t window dressing; it becomes the basis for trust up and down the supply chain.
The cycle of feedback never ends. Each time a customer’s batch deviates from expectation, our analysts pour over chromatograms to trace the source. Sometimes the root cause lies in a tweak to raw material supplier processes; other times, it links back to seasonal shifts in temperature or a process parameter nudged by mistake. The solution isn’t just about fixing the batch at hand but updating SOPs and cross-training plant staff so new mistakes don’t creep in.
Big customers in pharmaceutical and crop science markets often share upcoming project requirements early, triggering custom-tailored campaigns. We match starting materials and analytical protocols as closely as possible to cut down on delivery risks later on. With regulatory filings, customers often require multi-year batch records and the ability to backtrack every process change. Our document management team integrates with process engineers to keep everything connected, accessible, and review-ready.
Maintaining consistent supply during market disruptions tests everything—sourcing, logistics, and technical troubleshooting. These trials teach more than any technical seminar. Each crisis leaves better systems in place, ready for the inevitable next round. As manufacturing teams, we share real lessons from recovery: how to redesign supply chains, how to create predictable production cycles, how to guarantee reserves for top-tier clients without shortchanging smaller partners.
“Quality by design” isn't a buzzword in the plant. Whether we’re mixing a new batch or auditing packing floors, our processes live and die by the data. Repeatable process signatures, goods-on-time shipments, and clear documentation mean customers know exactly what they’re getting every time. Each batch tag, transport manifest, and analytical sheet forms part of a web of accountability. Fielding inquiries from customers and regulators alike, our answers draw on lived experience rather than abstract guidelines.
Repeated use of 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro- in new applications drives us to keep tweaking and stretching process boundaries. The steady demand for cleaner, higher-yielding batches leads to trialing new solvent systems, refining in-process controls, and automating sample checks. We test alternatives to conventional synthesis to reduce waste at the source and trim timelines without trading off on purity or stability.
Partnerships with academic labs and customer research teams go beyond one-off projects. Insights from real use cases—how the molecule reacts under irradiation, what impurities matter most for a new kinase inhibitor, what stability profile matters most in a field trial—feed back into our own process improvement discussions. We act as much as technical advisors as we do as raw material suppliers. The point isn’t to grow the product range for its own sake, but to deepen the reliability of every batch. Customers in biotech, custom synthesis, and agrochemical R&D drive us to raise the standard with every campaign.
Raw material quality, handling expertise, and willingness to shoulder short-term losses for long-term growth form our real competitive edge. The difference from other sources starts to show across seasons of steady, honest production rather than with introductory offers or glossy claims. Repeat customers ask for the same operator’s notes, the same inspection sheets, knowing that knowledge outpaces shortcuts every time.
Innovation isn’t about grand gestures. In the plant, it’s the choice to trial a new purification column or schedule maintenance on vent scrubbers before they hit critical loading. On the supply front, it looks like staying ahead of regulatory trends so supply never stumbles due to missed hazard classification or overlooked transport regulation. This hands-on, day-by-day improvement gives the industry products they can use now and solutions for surprises which inevitably come.
As manufacturers, we own the whole risk chain from shipment back to raw material. Safety audits, routine equipment checks, PPE training—these are non-negotiable for everyone who walks onto the site. We’ve seen impatience or corner-cutting result in not just paperwork headaches but physical danger. Sincere safety culture isn’t about slogans but procedural rigor, openness to reporting near-misses, and dedicated follow-up. Each improvement comes from real incidents, not hypothetical scenarios.
End-users expect more than a certificate or a batch record; they count on transparency about solvent residues, trace metals, or even potential allergens—all the side points that could impact their own product downstream. Our commitment comes from knowing every detail matters to someone on the other end. Each question about stability testing, repack protocols, or shelf-life length gets shared openly. We keep all teams looped in, from technical to logistical, so customers get straight answers tied to the real run conditions of their batch.
Our connection to 3-pyridinecarboxaldehyde, 5-chloro-2-fluoro- isn’t just about product launches, catalog entries, or one-off shipments. It’s about building a legacy of repeat performance, transparent relationships, and relentless pursuit of better production practice. Our teams keep raising the bar not for marketing, but for the chemists, researchers, and engineers whose own work relies on the trust we’ve earned, shift by shift for years. This discipline and care define the difference between true manufacturers and those merely trading names and paperwork.
