|
HS Code |
365716 |
| Iupac Name | 5-(Trifluoromethyl)pyridin-2-ol |
| Molecular Formula | C6H4F3NO |
| Molecular Weight | 163.10 g/mol |
| Cas Number | 22236-12-9 |
| Appearance | White to off-white powder |
| Melting Point | 68-72°C |
| Solubility In Water | Slightly soluble |
| Smiles | C1=CC(=NC=C1O)C(F)(F)F |
As an accredited 5-(trifluoromethyl) -2-hydroxypyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 25g package features a sealed amber glass bottle, clearly labeled with hazard symbols and the product name "5-(trifluoromethyl)-2-hydroxypyridine". |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 120 drums, each 200 kg; total net weight 24,000 kg, securely packed for safe international shipment. |
| Shipping | 5-(Trifluoromethyl)-2-hydroxypyridine is shipped in tightly sealed containers, protected from moisture and light. It is handled as a laboratory chemical with caution, and is typically shipped at ambient temperature unless specified otherwise. Ensure compliance with all local, national, and international chemical transportation regulations during shipping. |
| Storage | Store 5-(trifluoromethyl)-2-hydroxypyridine in a tightly sealed container, away from moisture, heat, and direct sunlight. Keep in a cool, well-ventilated, and dry area, isolated from incompatible substances such as strong acids and bases. Properly label the container and restrict access to trained personnel. Use appropriate personal protective equipment (PPE) when handling the chemical. |
| Shelf Life | **Shelf Life:** 5-(Trifluoromethyl)-2-hydroxypyridine is stable under recommended storage conditions, typically retaining quality for at least 2 years. |
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Purity 99%: 5-(trifluoromethyl) -2-hydroxypyridine with 99% purity is used in pharmaceutical intermediate synthesis, where high purity ensures minimal side reactions and greater yield. Melting point 82°C: 5-(trifluoromethyl) -2-hydroxypyridine with a melting point of 82°C is used in solid-phase organic synthesis, where thermal stability enables precise temperature control processing. Molecular weight 163.09 g/mol: 5-(trifluoromethyl) -2-hydroxypyridine at a molecular weight of 163.09 g/mol is used in drug discovery research, where its defined mass supports accurate compound formulation. Stability at pH 7: 5-(trifluoromethyl) -2-hydroxypyridine stable at pH 7 is used in biological assay development, where neutral pH stability maintains compound integrity during testing. Particle size ≤ 10 μm: 5-(trifluoromethyl) -2-hydroxypyridine with particle size below 10 μm is used in fine chemical production, where small particle size provides enhanced reactivity and dispersion. Solubility in DMSO 50 mg/mL: 5-(trifluoromethyl) -2-hydroxypyridine with DMSO solubility of 50 mg/mL is used in high-throughput screening, where high solubility facilitates preparation of concentrated stock solutions. Water content ≤ 0.2%: 5-(trifluoromethyl) -2-hydroxypyridine with water content not exceeding 0.2% is used in anhydrous chemical reactions, where low moisture prevents hydrolysis and ensures reproducible results. Storage temperature 2–8°C: 5-(trifluoromethyl) -2-hydroxypyridine stored at 2–8°C is used in reference material banks, where controlled storage preserves compound stability over time. UV absorbance (λmax 278 nm): 5-(trifluoromethyl) -2-hydroxypyridine with UV absorbance at 278 nm is used in analytical method validation, where distinct absorbance enables accurate quantitation. |
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Experience guides every decision here, and after many years refining our production lines, 5-(trifluoromethyl)-2-hydroxypyridine carries the quality mark we’ve worked for. The chemical business can look crowded from a distance but only a few producers oversee every batch, monitor purity themselves, and know exactly what leaves their plant. We built our reputation on the discipline of hands-on manufacturing, not on trading or simple reselling.
This approach to chemical synthesis gives us a unique relationship with our materials. Years of tight process development make us see every batch of 5-(trifluoromethyl)-2-hydroxypyridine as more than just a line item. Regular, real-world feedback from synthetic chemists, formulation teams, and research scientists shapes the quality controls. Consistency means more than paperwork; we see it in spectroscopic traces and customer runs.
This compound, model number 80360-87-6, fits squarely in the portfolio of active intermediates. As both producer and user, we understand its value in pharmaceutical research, agrochemical development, and materials science. Solid, off-white to light yellow crystalline powder, this molecule’s distinct trifluoromethyl group on the pyridine ring brings real improvements to certain syntheses. Where many pyridines evade control in some reaction steps, this modification gives chemists a handle on reactivity and selectivity. The hydroxy group at the ortho position gives new possibilities for further transformation, especially in Suzuki couplings, functional group substitution, and heterocyclization.
We’ve seen many inquiries from development teams who tried standard pyridines and ran into barriers—poor solubility, unwanted side products, or challenges in purification. By providing 5-(trifluoromethyl)-2-hydroxypyridine as a high-purity powder, tested and released only after we confirm through GC-MS, HPLC, and NMR, users work with confidence. Typical purity exceeds 98%, and we reference the original spectral libraries to verify identity.
Sourcing reliable starting materials stands as the non-negotiable foundation. We qualify every supplier through audits and on-site inspections rather than just online exchanges. Semi-automated reactors process the fluorinated intermediates in inert atmospheres. Staff skilled in troubleshooting step in directly if any deviation appears on the control charts. This hands-on approach prevented minor blips from turning into failed batches in previous campaigns, so we protect customers from supply interruptions.
Solvents and reagents enter the process only after passing our own in-house assay protocols—no shortcuts. We track every lot with barcoded systems, but more importantly, someone on the team actually compares the sample to known reference material. Analytical teams run FTIR scans before and after the cleaning and crystallization steps, so we catch problems before packaging. Experience with degradation pathways leads us to store 5-(trifluoromethyl)-2-hydroxypyridine in temperature-controlled rooms, away from moisture and direct light, which prolongs shelf stability and helps chemistry teams avoid unpleasant surprises.
Synthetic chemistry never stands still. The need for new building blocks that combine reactivity, manageability, and safety has never been greater in pharmaceutical labs and crop science pipelines. The trifluoromethyl group increases the biological profile diversity compared to non-fluorinated or mono-fluorinated pyridines. Our direct customers report that this product allows for easier installation of fluorinated motifs, which serve as metabolic blockers or tune lipophilicity in pharmaceutical targets.
In agrochemical R&D programs, lead diversification often hits a wall when only standard pyridines are on hand. Adding a fluorinated group not only opens up SAR space but can also alter environmental fate. Colleagues in the field highlight improved uptake profiles for analogs developed from our compound versus plain hydroxy-pyridines.
Polymer chemists studying advanced materials recognize the value added by controlled functionalization at the ortho position. Proton NMR analysis always reveals the signature shift from the trifluoromethyl group—an unmistakable sign that reaction pathways can be steered cleanly. That kind of feedback, collected by working side-by-side with application scientists, refines our own process over time.
Every batch comes packed with a focus on robust, contamination-free handling. We avoid the generic drums used for lower grade materials, using lined HDPE containers and tamper-evident seals instead. On our end, trained operators load the final product only after secondary verification of moisture content and bulk density, which matters for weighing and dissolution.
Product experience in university and industry settings points toward reliable handling. The crystalline powder pours smoothly, resists caking, and dissolves readily in common polar organic solvents. Teams appreciate quick filtration and limited need for further purification before entering reaction vessels. Where some suppliers provide inconsistent material that calls for re-crystallization or charcoal treatment by the end user, we deliver a preparation that works as intended out of the box.
Sensible lab protocols still apply, as 5-(trifluoromethyl)-2-hydroxypyridine demands the standard safety precautions associated with small-molecule research. We share handling experience openly—ventilated areas and gloves as a minimum, plus double-bagging for storage during longer projects. Customers who request larger lots for scale-up access technical support from process chemists, not just a call center or generic instructions.
At a fundamental level, many pyridine derivatives compete for the same slots in organic synthesis. The unsubstituted 2-hydroxypyridine or derivatives lacking the trifluoromethyl group have a long history but limit what medicinal or crop chemists can achieve. The electron-withdrawing CF3 group in the 5-position alters the electron density of the ring, offering new selectivity in electrophilic aromatic substitution—which drives cleaner routes to downstream analogs.
Process measurements here showed dramatic differences versus similar compounds in key metrics. For one, powder flow rates during weighing hit higher, more reproducible marks than with bulkier alkyl-substituted pyridines. In catalytic reactions, our product demonstrates improved turnover numbers, based on comparative customer trials, owing to decreased steric crowding and increased polarization. The compound holds up better in storage: in stress tests, the material preserved color and purity much better than common methoxy- or methyl-substituted alternatives.
Even in the small details—like the ease of monitoring the progress of reactions involving our compound by NMR or HPLC—the differences stand out. Fewer unidentified byproducts show up in downstream purification, reducing time spent on troubleshooting or column work. It’s these practical differences, not just abstract reactivity numbers, that get cited back to us by partner labs and pilot plants.
Supply chain disruptions and rising global demand for specialty fluoro-organic chemicals raise the bar for reliable sourcing. We hold inventory in finished goods and also at the intermediate stage, so our partners do not have to delay projects awaiting distant shipments. Owning the actual process eliminates the common pitfalls experienced with middlemen—where information, consistency, or even authenticity can slip through the cracks. Each certificate of analysis traces back to our records, not to third-party traders.
Splitting our output between custom syntheses and catalog orders means we’ve clocked unexpected spikes in demand without short-changing either side. Our planners tie lot release timing to ongoing customer projects, which limits obsolete stock and guarantees fresher product dates. We stake our reputation on these professional habits—and customers reciprocate by calling us again rather than shopping around for who simply quotes the lowest number.
The market for specialized nucleating agents, medicinal building blocks, and advanced agrochemical test intermediates will only expand. Direct conversations with bench chemists, R&D directors, and regulatory compliance teams fuel continuous process improvement. We measure success by repeat orders from sophisticated users, not by warehouse churning. Investments in analytical instrumentation, staff training, and safe packaging stem from this commitment, not external marketing requirements.
Turning out high-quality 5-(trifluoromethyl)-2-hydroxypyridine at scale never means ignoring the waste stream. For years, the team has built solvent recycling into every batch. By running overhead condensers and vacuum stripping, we recover upwards of seventy percent of organic solvents. That effort comes both from a respect for community standards and from daily responsibility as direct producers.
Our late-stage purification steps use water only for final rinses, minimizing contaminated aqueous discharge. Spent catalysts, excess starting reagents, and off-spec material all receive documented disposal through vetted partners, reviewed annually. Those procedures have evolved because our own site faced regulatory scrutiny before industry requirements caught up. That experience delivers assurance to customers that their projects do not hide a hidden environmental impact.
Shifts toward lower energy use go beyond mere compliance. Variable-speed drives on filtration and drying equipment drive electricity reductions. Innovation on the floor delivered modest but real improvements in cycle time across the last five years. By connecting usage rates and yield metrics directly with production manager accountability, waste drops year on year—not as part of a marketing campaign, but as a result of daily discipline demanded by our own standards.
The kind of analytical work that supports reliable 5-(trifluoromethyl)-2-hydroxypyridine production demands a dedicated QC unit. Standard assessments include proton and fluorine NMR, complemented by high-resolution mass spectrometry. Every lot includes at least three independent analyst sign-offs before leaving site.
Data transparency takes priority. We supply full analytical chromatograms, not selected highlights. Users see impurity profiles, water content, and confirmation spectra. Over the last decade, this approach cut down on follow-up requests, reduced disputes, and strengthened collaboration on troubleshooting. Many chemists value seeing the same profile we see—not just a written assurance, but a mirror of our plant reality.
Statistical process control charts line the production office walls. These simple patterns point to out-of-control processes long before a bad result hits a customer. In our experience, rapid correction at this stage saves long, unproductive analysis downstream. Feedback loops built into every campaign yield genuine improvements, illustrated by narrower melting point ranges and sharper main peaks on HPLC in recent years.
Competition from producers who short-cut steps or dilute their quality with repackaged material always lurks in specialty chemicals. Open-ended warranties, continual technology upgrades, and willingness to let customers visit the plant create trust. Over time, direct conversations with users about what works—or where improvements could be made—drive our adaptation. For instance, batch size scalability sometimes requires new mixing protocols or crystallization steps; we test those openly and share what works, building reliability not just for ourselves but for users scaling frontier chemistry.
Custom application requirements, such as unique purity thresholds, require real flexibility in our process design. Feedback loops between our floor chemists and external project leads achieve these results: a new filtration setup for ultra-high purity demands, tailored micron sizing where formulations demand minimal dust, or implementation of in-line particle size testing. On-the-ground experience resolves bottlenecks long before the finished intermediate ships.
Running a chemical site today means aligning practical safety, environmental stewardship, and customer requirements—without bureaucratic slowdowns. On-site EMS teams, built into our manufacturing floor—not siloed away—catch safety concerns at the point they matter. This level of integration would be missing in traded or drop-shipped products, where direct experience of the material or process simply does not exist.
Direct manufacturing involvement in 5-(trifluoromethyl)-2-hydroxypyridine production translates to direct confidence, for ourselves and the teams using this intermediate for innovative synthesis. The best evidence comes from a simple set of stories: projects that stayed on-track because of stable supply, product launches that hit purity targets from the first kilogram, and lab teams who send thanks for reliable processability.
The future of specialty pyridine intermediates rides on a blend of technical know-how, practical discipline, and direct partner support at every production step. From initial audits of raw material sources to each test before shipment, every action answers a core question: does this meet the test on the bench or in production? For us, the answer remains clear—real partnership, practical experience, and continuous engagement guide each kilogram of finished product.
