|
HS Code |
101344 |
| Name | 6-Cyano-2-naphthol |
| Chemical Formula | C11H7NO |
| Molecular Weight | 169.18 g/mol |
| Cas Number | 39232-21-8 |
| Appearance | light yellow to beige powder |
| Melting Point | 193-198 °C |
| Solubility | Slightly soluble in water, soluble in organic solvents |
| Purity | Typically ≥98% |
| Storage Conditions | Store at 2-8°C, protect from light |
As an accredited 6-Cyano-2-naphthol factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 6-Cyano-2-naphthol is packaged in a 25-gram amber glass bottle, sealed, and labeled with chemical details and hazard warnings. |
| Container Loading (20′ FCL) | 20′ FCL loading for 6-Cyano-2-naphthol ensures secure packing, moisture-proof protection, and efficient container space utilization for safe transit. |
| Shipping | 6-Cyano-2-naphthol is shipped in tightly sealed containers, protected from light and moisture. It is handled as a hazardous chemical, typically packed according to regulatory guidelines for safe transport. Labels indicating its chemical identity, hazard class, and safety precautions are affixed, and all shipping complies with international and local chemical transportation regulations. |
| Storage | 6-Cyano-2-naphthol should be stored in a tightly sealed container, away from moisture and direct sunlight, in a cool, dry, and well-ventilated area. Keep it away from incompatible substances, such as strong oxidizing agents and bases. Proper chemical labeling and secondary containment are recommended to prevent spills or accidental exposure. Use gloves and safety glasses when handling. |
| Shelf Life | 6-Cyano-2-naphthol should be stored cool, dry, and protected from light; shelf life is typically several years under proper conditions. |
Competitive 6-Cyano-2-naphthol prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615371019725 or mail to sales7@boxa-chem.com.
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Tel: +8615371019725
Email: sales7@boxa-chem.com
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Bringing years of hands-on manufacturing experience to the table, I have watched the evolution of specialty chemicals—from batch processing to automation, from manual purity checks to digital analytics. Among the many compounds we produce, 6-Cyano-2-naphthol stands out for its unique blend of structure and function. In a marketplace crowded with imitators, a manufacturer’s voice makes a difference. We understand this molecule from the ground up, not just by formula but by the nuances that develop through production, testing, and application feedback.
We produce 6-Cyano-2-naphthol as a finely controlled, typically off-white powder, aligning each lot to strict internal parameters established over years of customer collaboration. Our material, recognized for its high purity, matches the expectations required for advanced organic synthesis and downstream transformations. We consistently target purity above 98% based on HPLC and NMR confirmations. Each synthesis run undergoes rigorous checks for residual solvents, isomeric impurities, and moisture content, because in complex organic building blocks, small deviations can derail a synthesis.
We have streamlined our process to deliver 6-Cyano-2-naphthol with a melting point between 196–200°C, which stays stable in practical terms for lab and pilot-plant settings. Crystal habit and grain size come from decades of optimization, feeding back from research labs and scale-up engineers. We recognize that consistency in crystallinity ensures predictable dissolution and mixing—details that mean the world when a chemist stands at the bench planning their synthesis.
A chemical’s story doesn’t start with the reorder; it begins with the raw materials. We have cultivated reliable upstream relationships with our supplier network, securing the naphthalene base and cyanation agents. Only with these relationships can we guarantee access to feedstocks that stay within approved specification ranges, controlling unintended byproducts and pollutant residues that would show up later in the process.
Our process involves direct cyanation under optimized conditions, maintaining careful pH and temperature control. We bypass the intermediate stages prone to side reactions, combining process economics with environmental responsibility. Process wastewater and off-gas are handled with continuous monitoring, not just ticking off regulatory boxes, but striving year-by-year to exceed emission targets and invest in solvent recycle loops.
Each batch of 6-Cyano-2-naphthol gets a full identification profile: melting point, IR, UV-vis, and NMR investigation alongside mechanical and moisture analyses. We do not send out any batch without knowing it meets every data point. Years in manufacturing teach hard lessons about trace impurity carryover—how a dozen parts per million of a regioisomer can impact downstream catalytic steps or even product color.
This compound often lands in research portfolios because of its aryl cyanide function with a nontrivial hydroxyl group, creating a platform for extended electronic modulation. Customers choose it for the unique chemical leverage that comes from naphthalene’s aromatic core, enhanced by the electron-withdrawing cyano group at position 6 and a hydroxyl at position 2. This configuration opens doors in synthesis unavailable to single-ring or para-substituted analogues.
Our partners in pharmaceutical discovery often share feedback about their experience with substituted naphthols. They confirm that 6-Cyano-2-naphthol brings not only a stepping stone for heterocycle formation but also a building block for specialty pigments or materials research. It goes beyond vanillin-style simple aromatics or overused mono-cyanoarenes.
The compound’s robust pi-system and functional handles make it invaluable for Suzuki and Heck couplings, cyclizations, and biaryl formation. Its solubility profile—adapted through years of process development—lets synthetic organic chemists avoid aggressive base conditions that would shatter less stable aryl cyanides.
I have seen this molecule bridge the gap between basic research and scaled commercial development. Chemists pursuing kinase inhibitors or fluorescent probes have relied on our consistency, knowing that side-product contamination or deviation in polymorph could set their timelines back by weeks. For pigment research, 6-Cyano-2-naphthol’s electron arrangements give rise to vibrant colors, stable under both UV and visible light—a property rarely obtained from simpler cyanoarenes.
One customer, scaling up an N-heterocyclic scaffold, demonstrated that switching from generic cyanonaphthol to our refined 6-Cyano-2-naphthol cut their side-product content by half, saving a full downstream purification step. That feedback came directly to our technical team, driving another round of process tightening. Each story echoes the reality: a product’s success depends not only on molecular formula, but also on control of the unseen, lot after lot.
Academic users cite its unique fluorescence and stability, using it for probes and sensors. Some describe how structure-reactivity relationships shift subtly with our material compared to others sourced elsewhere, linking the effect to differences in crystal growth or contamination level. These reports come from peer-reviewed publications and direct correspondence—real evidence that production diligence changes research outcomes.
On paper, it might seem like 6-Cyano-2-naphthol is a commodity item: naphthalene chemistry, basic cyanation, straightforward crystallization. Yet our direct experience says otherwise. Low-purity or poorly characterized material won’t just slow synthetic progress; it erodes confidence in results. The low-cost versions often contain off-target byproducts—halonaphthalenes, residual starting material, or over-cyanated derivatives.
Over years, we have debugged complaints about failed couplings or variable pigment behavior, only to trace the root cause back to uncertain raw materials or corner-cutting during purification. Manufacturing demands patience, discipline, and an understanding that reliability pays back over time. Our philosophy digs deeper than lot-to-lot testing; it involves feedback loops from bench-scale users, process engineers, even regulatory reviewers.
Price-centric suppliers may offer basic COA documents and little else. We support each shipment with batch spectral data, provide sample retention for verification, and welcome technical audit requests. The difference shows up most obviously when a process goes awry, and a troubleshooting team needs detailed analytics—spectra, impurity logs, environmental audit trails. Having these details on hand shortens time lost to uncertainty.
Through hands-on process development, we saw firsthand that minor changes in cyanide addition or base neutralization could impact overall product stability. Early process runs sometimes delivered unsatisfactory batches—yellowish hues, broad melting ranges, stubborn filter-cake. We invested years into chromatography methods and pH control, shrinking variability run-to-run and bringing the product profile within a tight envelope.
Besides process tweaking, we developed partnerships with packaging suppliers. Chemically stable, moisture-barrier-lined containers arrived after testing five packaging prototypes. Shipment to North America through inland routes required changes to desiccant systems and pallet treatment. These aren’t marketing slogans—they are hard-won lessons from logistics missteps and regional humidity effects.
To comply with international transport regulations, we implemented full batch traceability, tying each container directly back to synthesis logs and environmental treatment records. Regulatory changes—from REACH in Europe to TSCA in the Americas—trigger in-house compliance audits. Operations managers maintain continuous communication with compliance officers, ensuring our production keeps pace with shifting legal demands.
It helps to explain differences by pointing to hands-on results. 1-Cyano-2-naphthol and 2-cyano-6-naphthol both carry electron-withdrawing groups on a naphthalene core, but the impact on reactivity differs by position. Steric hindrance, coupling yield, and aromatic substitution rates all change between isomers. Researchers tell us our 6-Cyano-2-naphthol performs with greater selectivity in ortho-substituted coupling reactions. Physical stability also shifts—a change in the naphthol position alters solubility in acetonitrile and tolerance to high-heat reaction conditions.
Compared to simpler aryl cyanides or mono-substituted naphthalenes, our compound provides a dual anchor for further functionalization. The hydroxyl group at the 2-position directs metalation and protects against over-reduction, a property seldom matched by generic naphthols. In contrast, substituted benzenes or single-position naphthols often lack the full synthetic handle range.
Feedback from advanced materials teams demonstrates how the spatial arrangement of the cyano and hydroxyl functions enables fine-tuning of optical properties. In low-temperature OLED research or polymer development, these contrasts become critical. Side-by-side comparisons show more predictable fluorescence and less degradation under voltage cycling for 6-Cyano-2-naphthol. Innovation on the bench always benefits from understanding these nuances.
For a manufacturer, producing chemicals is never just synthesis and filtration; it’s about building trust through reliable supply and forward-thinking stewardship. Our experience during global logistical disruptions emphasized the importance of maintaining robust raw material stocks and secondary sourcing channels. When local transport stalled, we shipped through alternate ports and communicated every development to long-term clients, minimizing potential project delays.
Regulatory attention has only intensified. As a registered manufacturer, every shipment of 6-Cyano-2-naphthol receives documentation aligned with international convention—SDS, transport certificates, and environmental safety logs prepared using internal compliance systems. Years before many competitors, we invested in electronic document management to accelerate customs clearance and client audits.
Production scale-ups sometimes reveal environmental tradeoffs. We run life-cycle analyses on processes—evaluating waste flow, recycling rates, and emissions. Cleaner batchwork doesn’t come cheap, but we learned to reinvest in closed-loop systems, solvent recovery, and reagent quality programs. By reporting our environmental indicators to clients, we earn not only compliance but also long-term trust.
Working as a manufacturer puts us in constant dialogue with users—from R&D directors at multinational pharma outfits to graduate students tackling their first multistep synthesis. We maintain technical support lines staffed by chemists who understand application bottlenecks. This collaboration extends from consulting on reaction conditions to explaining spectral anomalies. Laboratories face enough unpredictability; receiving dependable material eliminates one variable.
We do not take a hands-off approach after sale. Follow-up often reveals insights that circle back into production—unusual impurities, batch-to-batch performance differences, or suggestions for packaging tweaks. Each point of feedback strengthens process controls, closing the loop between the customer’s bench and the factory floor.
Customers sometimes invite us to collaborate on developing new routes or solving unexplained yield drops. In one project, our technical advice on reaction sequencing, tied to deep knowledge of our product’s reactivity, let the client save significant time and materials. We know the molecule and its quirks, not just because we produce it, but because we study its every effect in the field.
In this industry, there’s no standing still. New synthesis strategies, tighter regulatory controls, and increasingly sophisticated applications keep us on alert. We invest in automation for faster turnaround, digital data management for traceability, and advanced purification to exceed purity demands. Environmental stewardship features in every capital investment—solvent recovery, carbon accounting, and energy efficiency shape our decisions.
We keep an eye on the future, collaborating with research partners on next-generation uses for 6-Cyano-2-naphthol. Advances in organic electronics, photonics, and catalysis require ever-more tailored building blocks. The feedback from these advanced teams finds its way into how we think about scale-up, impurity profiling, and supply reliability. As new semiconductor projects seek materials with defined electronic profiles, our production expertise ensures we adapt—and often lead.
Supply chain sustainability means tracking sourcing, verifying every step, adapting as geopolitical or regulatory currents shift. We have shifted suppliers, adjusted batch planning, and adopted new testing standards to meet international customer requirements. Experience reminds us that being a chemical manufacturer calls for vigilance, agility, and close communication at every step.
Looking back over the years, every challenge—from product stability to regulatory innovation—has reinforced our belief in hands-on, accountable manufacturing. 6-Cyano-2-naphthol, to us, is more than a product code. It represents hours spent refining crystallization, discussions on impurity sources, and lessons in logistics and compliance. Our success flows directly from these accumulated insights.
For you—the research chemist, the pilot-plant manager, the quality director—our product stands as a testament to what manufacturing should deliver: consistency, transparency, and partnership. We know the story of this molecule doesn’t end in the bottle; it continues in your lab, in the results you drive, and in the breakthroughs yet to come.
