|
HS Code |
166657 |
| Iupac Name | 5-fluoro-2-methoxy-pyridine-4-carbaldehyde |
| Molecular Formula | C7H6FNO2 |
| Molecular Weight | 155.13 g/mol |
| Cas Number | 868257-10-1 |
| Appearance | Pale yellow to light brown solid |
| Melting Point | 58-60°C |
| Solubility | Soluble in common organic solvents (e.g., dichloromethane, ethanol) |
| Smiles | COC1=NC=C(C=C1F)C=O |
| Inchi | InChI=1S/C7H6FNO2/c1-11-7-6(8)2-5(4-10)3-9-7/h2-4H,1H3 |
As an accredited 5-fluoro-2-methoxy-pyridine-4-carbaldehyde factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle, 25g, sealed with a PTFE-lined screw cap; labeled “5-fluoro-2-methoxy-pyridine-4-carbaldehyde,” hazard symbols, lot number. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 5-fluoro-2-methoxy-pyridine-4-carbaldehyde ensures secure, compliant packaging in drums or fiber barrels, maximizing space efficiency. |
| Shipping | 5-Fluoro-2-methoxy-pyridine-4-carbaldehyde is shipped in tightly sealed containers to prevent moisture ingress and degradation. It is packed according to standard chemical transport regulations, labeled with appropriate hazard information, and cushioned to avoid breakage. The package includes safety documentation and is shipped via approved couriers specializing in chemical logistics. |
| Storage | **Storage Description:** Store 5-fluoro-2-methoxy-pyridine-4-carbaldehyde in a tightly sealed container under inert atmosphere, in a cool, dry, and well-ventilated area, away from sources of ignition and moisture. Protect from light and incompatible substances such as strong oxidizers. Refrigeration may be recommended. Label appropriately and follow local chemical storage regulations for hazardous organic compounds. |
| Shelf Life | Shelf life of 5-fluoro-2-methoxy-pyridine-4-carbaldehyde is typically 2-3 years when stored in a cool, dry, and dark place. |
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Purity 98%: 5-fluoro-2-methoxy-pyridine-4-carbaldehyde with a purity of 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield of target heterocyclic compounds. Melting Point 72°C: 5-fluoro-2-methoxy-pyridine-4-carbaldehyde with a melting point of 72°C is used in medicinal chemistry research, where it facilitates controlled solid-phase reactions. Stability Temperature 45°C: 5-fluoro-2-methoxy-pyridine-4-carbaldehyde stable up to 45°C is used in organic synthesis protocols, where it provides reliable storage and handling during process development. Molecular Weight 157.12 g/mol: 5-fluoro-2-methoxy-pyridine-4-carbaldehyde with a molecular weight of 157.12 g/mol is used in analytical reference standards, where it enables accurate mass spectrometry calibration. Particle Size <75 µm: 5-fluoro-2-methoxy-pyridine-4-carbaldehyde with particle size less than 75 µm is used in formulation of fine chemical libraries, where it promotes uniform dissolution and reactivity. Water Content <0.5%: 5-fluoro-2-methoxy-pyridine-4-carbaldehyde with water content below 0.5% is used in moisture-sensitive reactions, where it reduces hydrolysis and side-product formation. Color Index ≤10 (APHA): 5-fluoro-2-methoxy-pyridine-4-carbaldehyde with a color index of ≤10 APHA is used in high-purity product manufacturing, where it ensures minimal chromophoric impurities affecting end-product quality. |
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5-Fluoro-2-methoxy-pyridine-4-carbaldehyde stands out for chemists searching for a steady building block in complex molecule assembly. In our own production lines, daily work revolves around the consistent quality of chemical intermediates. Synthetic efficiency depends on repeatable performance, not only on paper but in the churning heart of reactors—often at odd hours and demanding timelines. Our process brings to the table both product reliability and scale flexibility, qualities valued by seasoned process developers.
This particular aldehyde, model 5F-2MeO-Py-4CHO, arrives as a pale crystalline solid that resists clumping and resists loss even at modest storage temperatures. Our lots pass HPLC and NMR scrutiny to ensure each run meets purity standards north of 98%. The stability, often a shortcoming with sensitive fluorinated pyridines, remains high as residual moisture falls below 0.2%, and we maintain tight control on residual solvents. Internal teams have seen firsthand how decomposed aldehydes foul downstream chemistry and inflate costs; our practices put real effort into tackling these frustrations long before product leaves the site. We rely on in-house glassware cleaning, neutral atmosphere handling, and immediate vacuum sealing—hard lessons from watching yields dip inexplicably during earlier production years when lesser standards crept into daily routine.
Our experience covers both pilot and plant-scale manufacturing, especially where this compound is brought into benzene ring engineering, and into an array of heterocyclic cores needed in pharma and crop protection. Compared to related aldehydes, addition of the fluoro and methoxy groups at these specific positions nudges the electronic environment—this alters reactivity profiles that support more selective coupling and less waste. Batch records trace far fewer side reactions when chemists employ this molecule for key steps like Grignard additions, acylations, or even for delivering the aldehyde as a masked intermediate.
We work closely with synthetic chemists at the bench and on the process side. Extended trials in kilo-lab settings revealed why it provides a more manageable substrate than unfluorinated or unmethoxylated analogues—there’s less byproduct haze clogging up chromatographic purification, and purification times drop considerably. Productive, repeatable runs show that the right substitution pattern trims down unnecessary labor, waste, and chemical purchases for post-reaction clean-up.
Chemists often ask for practical distinctions between this compound and other pyridine carbaldehydes. Working every day with both 2-methoxy-4-pyridinecarboxaldehyde and its unsubstituted version, we find the substitution choices matter for more than theory. The fluoro group on the 5-position, for example, drives subtle differences in both reactivity and handling. In practice, our operators report reduced off-gassing and noxious odor compared to some chlorinated alternatives. Handling becomes safer with modern containment but, even under legacy fume hoods or basic industrial setups, our team records fewer instances of equipment corrosion.
Downstream, the fluoro-methoxy structure supports more robust reactions—nucleophilic attack happens where chemists plan, at a rate that matches theoretical calculations. We see fewer reruns and less troubleshooting on scale-up. Unsubstituted pyridine carbaldehydes, for comparison, lead to greater batch-to-batch variability, especially under more aggressive catalytic or reductive conditions. Our experience suggests that skipping careful substrate engineering up front can manifest as weeks of lost time in late-stage production.
Our facility uses real-world test conditions to judge batch performance, not just lab-bound purity numbers. We rely on highly resolved proton and fluorine NMR to catch trace anomalies. The compounds always undergo batchwise GC-MS and high-resolution LC-MS checks, which help us catch fragmentation signatures that hint at instability in the aldehyde. In terms of particle characteristics, our staff has honed a drying and sieving process over several years to avoid agglomeration—ease of sampling becomes critical in maintaining consistent input across multi-step synthesis. Teams packing our product into bulk containers focus on breakthrough issues, like clumping after cold storage or residual static that triggers material loss during transfer. Our records show that every minute detail, which can sound like a tedious side note in some specification sheets, brings real payback in reduced downstream troubleshooting for clients and ourselves.
Comparison with other production sources confirms a practical point: materials boasting identical specifications on paper can behave differently in demanding plant scenarios. Staff here look through the full lens—color, particle spread, moisture pickup, packing and flow data—since this affects not just productivity, but also the safety of every technician in the handling chain. Several clients, moving away from sourcing via traders, noticed measurable improvements on reaction runs when supplied directly from our in-house batches—less foaming, greater consistency in reaction yields, and simplified work-ups.
5-fluoro-2-methoxy-pyridine-4-carbaldehyde functions as a modular block in several generations of investigational pharmaceuticals and high-value agrochemical compounds. Specifying it correctly at the design stage has reduced problems for both in-house and partner research groups. Our collaborations across multi-year cycles—ranging from milligrams to tons—have put us in direct contact with researchers seeking clean, predictable inputs for library synthesis. In many screening campaigns, the use of an aldehyde with a tightly defined substitution produces not just greater hit rates in bioactivity assays, but also reduces clean-up steps and associated costs in late discovery.
Innovation only delivers its potential when raw material suppliers provide true reliability where it counts. Faulty or inconsistent batches force R&D teams to waste valuable time repeating structure confirmations, or even questioning their own reaction schemes. Reducing such interruptions has been a direct benefit seen by analytical chemists working with our materials. The ability to move from a 100 mg pilot reaction to a multi-kilo run, without unexpected impurities creeping in, stands at the center of productive research relationships. The compound’s electron distribution, modulated by its fluoro and methoxy substituents, supports a range of C–H activation protocols and Suzuki couplings, which opens doors for inventive late-stage derivatization—a vital component in ever-faster research pipelines.
Problems at the bench often boil down to the quality of input chemicals. Symptoms like color changes, poor dissolution, unexpected exotherms, or reduced yield all trace back, in our experience, to overlooked quality attributes at the intermediate stage. Our approach as a direct manufacturer avoids band-aid solutions and focuses on root causes. We have invested in incremental improvements from temperature-controlled storage, faster packaging lines, to dedicated drum washing stations. Every small fix, learned from a failed or delayed customer run, feeds directly into our revisions—no shortcuts, no passing blame upstream.
Our technical support team responds rapidly with batch data, including archived spectra and impurity profiles, because we understand the cost of waiting for answers. On multiple occasions, early identification of minor by-products or residual moisture, based on reports from end users, prompted us to fine-tune drying protocols and intake testing methods. This hands-on, feedback-driven process distinguishes what we do from trading houses who never own product accountability. We find that solutions materialize faster when dialogue is routine and direct—chemists on both sides can move away from abstractions and focus on real outcomes. In several customer projects, what appeared as a mysterious drop in intermediate yield got resolved by jointly identifying subtle differences in melting range and particle size between batches, knowledge earned by chemical hands, not abstracted in paperwork.
Experience shows scaling chemistry is more art than routine, especially for sensitive intermediates. We routinely handle transitions from 100 g pilot to 200 kg campaigns—always preserving purity and reactivity. The process design team works in lockstep with operations, orchestrating not just the initial synthesis, but every downstream packaging and logistics step. For newer clients, the ability to access the same batch properties as those validated in the research phase means less wasted time in requalification and fewer late-stage surprises. Concepts like “lab scale” purity often fall apart unless backed up by continuous monitoring and hands-on adjustments as the batch size grows.
Each scale-up brings its own hurdles: temperature gradients, solvent dynamics, agitation mysteries. Observing product losses during filtration or transfer stages on pilot runs prompted our engineers to implement closed-system transfers and revised filter-washing techniques. We take pride in closing gaps between laboratory expectation and plant execution. Documenting every step, observing the appearance and flow, we catch shifts before they snowball. Data is no replacement for lived process—operators bringing in lessons from dozens of previous runs catch issues before QC even runs its tests. This lived expertise is breathed into every drum hitting the shipping dock.
We see regulatory compliance not as a box-checking exercise but as part of our everyday survival. Stringent batch documentation and traceability save pain in the rare event of an investigation or recall. The fluoro and methoxy motifs call for particular attention in waste treatment—chlorinated and fluorinated streams need proper abatement rather than shortcutting to landfill. Our on-site environmental controls, with real emission capture and trained staff, grew out of past mishaps when outsourced waste firms botched basic protocols. Our people know from experience that safe handling not only protects the brand but shields workers and surrounding communities. Regular refresher training, real PPE, certified storage areas, and responsive management matter more than cursory safety sheets handed out once a year.
Our feedback loop does not end with legal compliance. We actively seek to lower VOC emissions, minimize packing waste, and design for closed-system charging wherever possible. This not only anticipates growing public scrutiny, but creates savings the business can reinvest. The greatest trust is earned by preventing, rather than merely reacting to, safety or regulatory slip-ups. Repeated audits—both internal and from our most demanding clients—push us into higher levels of assurance every year. These aren't just words, but lived reality for every technician and engineer in our halls.
The story of 5-fluoro-2-methoxy-pyridine-4-carbaldehyde in our production facility wraps around the people who make it real. Production staff spend daily shifts monitoring reactors, calibrating equipment, and verifying fine details that distinguish crops of premium product from problem batches. Chemists who find efficiency in its aldehyde function or subtleties in its reactivity owe those benefits to teams adjusting flows and temperatures, often under real strain and just-in-time conditions. Trust in our product begins with the lived attention of those who know what every processing sound and sight means in both calm and chaotic conditions. Reputations are earned every shift by the watchful hands of colleagues who can spot pre-troubles before instruments do.
In open dialogue across production, R&D, and client support, we trade lessons learned, skip bureaucratic delays, and tackle every request with both humility and expertise. Several failed early launches taught us that polished documents can't mask run-of-the-mill chemicals; only hands-on accountability delivers steady, world-class intermediates. For teams transferring a reaction or shifting a full project’s input to our manufacture, relief comes from constant and open updates, lived transparency, and refusal to let minor doubts go unaddressed. We manufacture not just for spec sheets, but for trust—and every bottle tells a history of hard effort, collaboration, and pride worked into each batch.
The calls we value most come after a first round of product succeeds in a difficult synthesis or proves itself on a production line, saving a day, reducing losses, or unlocking a route that stumped another supplier. Direct lines to our site mean problems encountered in Japan, Germany, or the US arrive at the same QC, the same technical teams, right here—no layers, no translation of meaning lost between distributor and manufacturer. It’s this interaction that saves clients weeks, even months, in validation cycles, as we can provide side-by-side batch histories or address concerns without spinning through layers of supply chain bureaucracy. More than one customer has told us directly that the benefit of manufacturing alignment shows up on the bottom line, as projects reach market readiness ahead of schedule.
Across hundreds of deliveries, we’ve seen that trust means more than a transaction—it’s built from each solved problem and every clear answer. We maintain strict recordkeeping not for marketing claims but because those records head off confusion, smooth audits, and speed up approvals. Rapidly sharing technical notes, tracking subtle shifts in feedstock or energy use, plugged straight into our own process improvements, closes the feedback loop constructively. Every operator, chemist, and support technician at our site knows the importance of real answers and even faster fixes—especially for those under pressure to deliver to the next milestone or process window.
More research-driven companies now look for not only product reliability, but also transparency and ethical management from upstream partners. We’re seeing tighter requirements in both documentation and environmental stewardship—and those who manufacture without shortcuts stand out. 5-fluoro-2-methoxy-pyridine-4-carbaldehyde often gets benchmarked against a wider portfolio of aldehydes. By remaining in control of our process from raw input through finished delivery, and engaging directly with clients, we’re able to point to fine details—like color, consistency, and real composition—that matter in the real working world. In markets shifting unpredictably, with raw material bottlenecks and logistics interruptions, working with genuine manufacturers provides uncommon peace of mind.
Companies no longer accept vague reassurance or generic supplier promises. Site visits, data-rich batch records, ongoing technical conversations—these turn a specialized chemical source from a variable into an asset. We take part in the wider professional world as active listeners, seeking ways to align production choices with client strategy, not just end-of-cycle reporting. Choice of raw material sets the stage not only for scientific innovation but also commercial viability, regulatory compliance, workplace safety, and broader community trust. With open doors and open records, we continue to supply this vital intermediate for companies counting on every gram, every shift, every outcome.
The evolution of specialty chemicals is driven at the intersection of bench chemistry, production scale-up, and global supply chain resilience. Our ongoing mission with 5-fluoro-2-methoxy-pyridine-4-carbaldehyde aims not just to deliver a functional aldehyde, but to partner across innovation, safety, and sustainable progress. The product itself reflects this—chosen for the way its design streamlines complex syntheses, reduces byproduct headaches, and bolsters reliability when research needs push past the theoretical into daily reality. This journey, measured in small-day victories rather than grand pronouncements, advances the field step by step. Our promise, shaped by direct experience and daily stewardship, stands as a steadfast commitment to every client, every project, and every person touched by the chemical world.
