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HS Code |
176056 |
| Chemical Name | 6-(Trifluoromethyl)-3-pyridinemethanol |
| Molecular Formula | C7H6F3NO |
| Molecular Weight | 177.13 g/mol |
| Cas Number | 898781-08-9 |
| Appearance | White to off-white solid |
| Melting Point | 88-91 °C |
| Purity | Typically ≥ 98% |
| Solubility | Soluble in DMSO, methanol |
| Storage Conditions | Store at 2-8°C, dry place |
| Smiles | C1=CC(=NC=C1CO)C(F)(F)F |
| Inchi | InChI=1S/C7H6F3NO/c8-7(9,10)6-2-1-5(4-12)3-11-6/h1-3,12H,4H2 |
As an accredited 6-(Trifluoromethyl)-3-Pyridinemethanol factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 25g chemical is packaged in an amber glass bottle with a secure screw cap and labeled for 6-(Trifluoromethyl)-3-Pyridinemethanol. |
| Container Loading (20′ FCL) | 20′ FCL container holds 6-(Trifluoromethyl)-3-pyridinemethanol securely packaged in drums or IBCs, maximizing volume and transit protection. |
| Shipping | 6-(Trifluoromethyl)-3-pyridinemethanol is shipped in tightly sealed containers under ambient temperature. Packaging complies with regulations for laboratory chemicals, protecting from moisture and physical damage. Safety data sheet (SDS) accompanies the shipment. This compound is generally shipped as a non-hazardous material, but local and international transport guidelines are followed to ensure safe delivery. |
| Storage | 6-(Trifluoromethyl)-3-pyridinemethanol should be stored in a tightly sealed container, protected from light, heat, and moisture. Keep at room temperature in a cool, dry, and well-ventilated area away from incompatible substances such as strong acids or oxidizers. Clearly label the container and ensure it is placed in a designated chemical storage cabinet. Use appropriate personal protective equipment when handling. |
| Shelf Life | 6-(Trifluoromethyl)-3-pyridinemethanol typically has a shelf life of 2-3 years when stored cool, dry, and tightly sealed. |
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Purity 98%: 6-(Trifluoromethyl)-3-Pyridinemethanol with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and product consistency. Melting Point 62°C: 6-(Trifluoromethyl)-3-Pyridinemethanol with melting point 62°C is used in solid formulation manufacturing, where it enables efficient process control and reproducibility. Molecular Weight 177.13 g/mol: 6-(Trifluoromethyl)-3-Pyridinemethanol with molecular weight 177.13 g/mol is used in agrochemical research, where it supports precision dosing and compound identification. Stability Temperature up to 120°C: 6-(Trifluoromethyl)-3-Pyridinemethanol stable up to 120°C is used in heated reaction systems, where it maintains chemical integrity without decomposition. Particle Size <100 µm: 6-(Trifluoromethyl)-3-Pyridinemethanol with particle size less than 100 µm is used in fine chemical blending, where it allows homogeneous distribution in mixtures. Moisture Content ≤0.5%: 6-(Trifluoromethyl)-3-Pyridinemethanol with moisture content ≤0.5% is used in moisture-sensitive syntheses, where it reduces side reactions and enhances reaction efficiency. |
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6-(Trifluoromethyl)-3-pyridinemethanol often emerges in conversations about fluorinated pyridine derivatives, especially among teams working in pharmaceutical and agrochemical development. From the first time we synthesized this specialty alcohol, the strong, clean chemical profile made it clear we were dealing with a compound that brings a unique set of attributes to challenging synthesis problems. With a trifluoromethyl group anchored at the sixth position and the methanol group at the third, this molecule balances reactivity and stability—a balance that’s always in demand during multi-step synthesis and scale-up.
As manufacturers, watching this product move from pilot to large-scale batches, the hands-on experience changes the way you think about selectivity and handling. Not every fluorinated intermediate maintains consistent physical properties batch after batch, especially after months of storage or transport. Our facility’s experience with crystallization, drying, and final yield put us in a good position to comment on the reliability of this compound. We focus on batch consistency for melting point and assay by validated HPLC; we’ve learned the value in regular moisture checks, since fluorinated alcohols can sometimes attract more water than expected. The finished product, when properly handled and packaged, shows almost no loss in either purity or usability for at least a year—critical for inventory planning and complex projects.
At first glance, the distinguishing line between this product and other pyridinemethanol derivatives seems subtle, but for someone at the reactor or overseeing purification, it’s the little differences that matter. The trifluoromethyl group doesn’t just serve as a chemical handle; it shifts the electronic nature of the molecule, attenuating some side reactivity and contributing to higher selectivity in downstream reactions. It can open up options in coupling chemistry, where competing nucleophiles or electrophiles might interfere in less engineered analogues. This factor crops up often in discussions with process chemists from other firms who want to know why yields hold steady through scale-up.
In practice, a manufacturer sees the full lifecycle of this compound. Stability during storage, behavior in solvents, compatibility with glass-lined equipment, and waste treatment requirements all rise to the surface. 6-(Trifluoromethyl)-3-pyridinemethanol has a distinct, crisp density; it doesn’t form sticky residues the way some similar products do, and our staff regularly note the difference in ease of filtration and recrystallization. We’ve compared head-to-head with non-fluorinated as well as other trifluoromethylated analogues and picked out the slightly higher volatility, which calls for careful control over vacuum distillation conditions. These observations highlight a product that behaves predictably in the plant—a quality impossible to appreciate without making hundreds of kilograms under live conditions.
Our conversations with pharmaceutical chemists, particularly those working in lead optimization for kinase inhibitors and CNS-active compounds, always circle back to the role of the trifluoromethyl group. The electron-withdrawing effect can tweak lipophilicity and metabolic stability, which allows medicinal chemists to dial in activity without shifting molecular weight excessively. As makers, we see the downstream impact play out in how frequently we refill orders from clients who are scaling preclinical or clinical candidates. These chemists need confidence in every batch and depend on zero-drama handling protocol—contamination or inconsistent purity means weeks lost.
In crop science, our partners innovate under regulatory pressure: restrictions surrounding solvent residues, process waste, and product stability force them to select starting materials and intermediates with a view toward long-term tracking and compliance. 6-(Trifluoromethyl)-3-pyridinemethanol often meets these goals because the molecule’s structure avoids breakdown routes that complicate some other classes of pyridine derivatives. The lasting stability in formulated products means companies reduce retesting and avoid regulatory headaches, and those advantages echo back to us in repeat business.
We take pride in controlling every stage, from sourcing precursors to sending out the final, packaged product. Production begins with careful selection of starting raw materials, monitored not only for purity but for trace metal content and residual solvents. Every operator on the floor knows the importance of clean glassware, tightly sealed vessels, and time-targeted sampling.
For 6-(Trifluoromethyl)-3-pyridinemethanol, we run multiple checks on intermediate purity before proceeding to the final workup. During scale-up, subtle changes—reaction temperature fluctuations or different agitation speeds—sometimes impact the particle size or solvent inclusion in the solid product. Our method, fine-tuned over multiple campaigns, ensures that what leaves our site does not surprise research teams with unexpected behavior. Chromatographic fingerprints and NMR spectra remain consistent, not just within regulated limits but with a degree of repeatability that supports demanding R&D and manufacturing uses.
Many companies emphasize compliance and traceability in their protocols, as do we, but for this particular product, real-world operator reports strengthen our confidence. Operators recognize the distinct aroma, the swift crystallization from ethers, and the product’s resistance to darkening after months on the warehouse shelf. This user feedback factors into process optimization, not just as an anecdote but as a crucial quality control input.
We manufacture and supply 6-(Trifluoromethyl)-3-pyridinemethanol under the internal model identifier “TFM-PM-OH” in lots sized for wide-ranging needs, from pilot projects requiring just kilograms to ongoing commercial needs of hundreds. Typical purity exceeds 99% by HPLC, and we ensure strict control for key physicochemical properties: melting point, water content, and related compounds. Our process integrates continuous improvement; recent upgrades to our drying and packaging line have reduced overall cycle time without sacrificing quality, especially during humid seasons.
Particle size distribution, always monitored, enables customers to go straight into synthesis or formulation steps without wasting time on milling or sieving. Consistent density and flow properties matter, particularly in automated dosing systems or after long-distance shipping, so we test these regularly and refine protocols accordingly. This lets downstream processes, including solid-liquid extractions and suspension preparations, proceed without hiccups. TFM-PM-OH maintains chemical integrity under most lab and plant storage conditions, provided direct sunlight and unnecessary heating are avoided.
Fluorinated pyridines can feature strongly characteristic odors and require basic personal protective equipment during handling. Our team always uses gloves, goggles, and proper ventilation, standard for compounds of this nature. We learned early in our production campaigns that operators should pay close attention whenever containers are opened after months of storage—the low vapor pressure deters rapid loss, but warmth or agitation can lead to more noticeable fumes. Packing materials were selected based on real-world shipping tests, rather than relying solely on laboratory simulations, ensuring product arrives in the same state we ship it out in.
Our warehouse staff follows a clear regimen, including regular rotations and checks for container integrity. We maintain a log for each batch, documenting temperature and humidity levels throughout the storage lifecycle. This data lets us anticipate and catch potential problems before they impact customers. Whenever we hear from users about handling experiences, good or bad, we feed the learnings back into process audits and training sessions. Years of this cycle make the handling and storage process nearly routine.
6-(Trifluoromethyl)-3-pyridinemethanol stands apart from non-fluorinated pyridinemethanol derivatives. Putting this into perspective, direct substitution with non-fluorinated analogues typically shifts both the chemical reactivity and physical handling properties. The trifluoromethyl group, beyond its benefits in medicinal chemistry, contributes to a higher overall molecular stability. We see higher recovery and fewer losses during chemical transformations such as oxidations or halogenations. Handling losses—a key metric for any manufacturer—show a measurable decrease, and fewer surprises appear during scale-up campaigns.
Comparing TFM-PM-OH with related trifluoromethylated alcohols, such as 2- or 4-positioned analogues, the 6-position offers noticeably better selectivity during aromatic substitution reactions. Teams aiming for highly regioselective syntheses in active pharmaceutical ingredients (APIs) or fine chemical intermediates see first-hand the impact this selectivity brings—fewer byproducts and less demand for downstream purification steps. From the plant floor, this translates into smoother operations, fewer equipment cleanouts, and shorter campaign timelines.
These distinctions often become clear only after experiencing operational realities number of times. The compound’s performance under stress—temperature cycling, long-term storage, exposure to non-ideal humidity—proves just how critical real-world manufacturing and testing are compared with small-batch, laboratory-scale assessments. Our repeat customers usually cite these hands-on, practical differences as their main reason for returning, not a technical datasheet or marketing promise.
Companies pursuing new active ingredients, advanced materials, or specialty reagents increasingly turn to our trifluoromethyl pyridinemethanol for the balance it brings to synthetic strategies. Where non-fluorinated analogues might falter in metabolite resistance or ballast, our product shows higher persistence and cleaner breakdown profiles. Analytical teams in pharma particularly value the clear, interpretable spectra that guests regularly produce—minimizing time spent resolving ambiguous or overlapping peaks. Precision medicine projects, agrochemical discovery work, and energetic materials research all see concrete advantages from using our reliable, sharp-cut material profiles. We’ve been approached by teams developing custom libraries or structure-based screens, who appreciate the blend of electronic and steric effects this compound offers. This real-world feedback, not just numbers from the QC lab, validates the manufacturing choices and line investments we make.
A consistent trend we see with new customers: product trial requests are rapidly followed by scaled, repeat orders. As manufacturers, we recognize that nothing speaks to the efficacy of a reagent like smooth integration into ongoing, deadline-driven campaigns. The absence of processing headaches builds trust quickly, and as chemists ourselves, we value that kind of straightforward collaboration. We hear about time saved on purification, process adjustments, and reaction troubleshooting. All of it adds up to meaningful value for innovation-driven customers.
Production and long-term handling of fluorinated organics bring a responsibility to protect both the people in our plant and the natural world outside. Our process control team works directly with environmental engineers to minimize waste and track every solvent stream. 6-(Trifluoromethyl)-3-pyridinemethanol offers an advantage because the molecule’s resistance to common breakdown pathways lets us recover and clean process solvents more efficiently than with other, less stable alcohols.
We maintain up-to-date documentation of chemical fate, disposal protocols, and exposure thresholds, although we keep this material out of public-facing marketing and focus on supporting customers with the real information that their teams require for compliance submissions. Prioritizing clean synthesis techniques—reducing side product formation and minimizing rinse-outs—earns us tangible savings and stronger compliance audits. This is a direct result of long-term investment in closed-loop reaction monitoring, solvent recycling, and batch traceability.
The responsible manufacturer has to stay attuned to shifting regulations. Recent years have seen increasing scrutiny of persistent organic pollutants and solvent use in chemical manufacture. Our commitment goes beyond minimum compliance; for every product, including our fluorinated pyridinemethanol, we run regular internal reviews of storage, transport, emissions, and waste handling. Customer audits are welcome, and we draw on direct operator experience to improve our reporting and preventative maintenance.
Over the past decade, we’ve witnessed firsthand how close ties between manufacturers and innovators create better outcomes. When customers bring unique process questions or request custom packaging options, we work through the practical implications together. And it’s not just about fulfilling a list of minimum specifications—some synthetic routes need modified handling, alternate solvent recommendations, or nuanced stability insights. We often recommend process tweaks based on tried-and-true plant experience, providing cautionary tales of things that didn’t work along with what did. Our technical teams remain available during the earliest feasibility tests through to campaign validation and commercial supply. This level of integration saves time, avoids failed runs, and empowers chemists to focus on their own innovation.
Another key area: formulation scientists appreciate up-to-date insights on particle properties, especially for dosing in automated environments or when prepping stock solutions for screening. Our own experience highlights the real cost of undetected agglomerates or unnoticed moisture creep—missed endpoints, stuck augers, wasted solvent. Honest communication, straightforward reports on each manufacturing lot, and the willingness to go back and improve a process when needed have paid off in long-term customer satisfaction and loyalty.
No matter how robust a compound might seem during a few campaigns, there’s always room to learn. We keep an open ear for field reports—storage anomalies, formulation surprises, reaction tweaks. As regulations around fluorine chemistry tighten and analytical standards climb ever higher, the true test comes through time and attrition. Our story with 6-(Trifluoromethyl)-3-pyridinemethanol keeps evolving: new equipment, refining crystallization cycles, tighter in-process controls, smarter solvent usage. Employees at every level offer feedback, from those loading drums to lab QC analysts and synthesis chemists, driving refinements. Each lesson earned on the plant floor, in the QC lab, or through customer dialogue, shapes the next campaign and informs the next technical advance.
Manufacturing is more than turning out a product to spec. It’s an ongoing relationship with both the chemistry and the teams who rely on what we deliver. 6-(Trifluoromethyl)-3-pyridinemethanol represents a clear example—where technical choice, operational experience, and customer application meet to generate lasting value for end-users. Everyone involved brings a depth of understanding that can only develop through years working directly with the molecule. We look forward to seeing how this compound continues to support new scientific advances, and we remain committed to sharing what we’ve learned with each new project and partner.
