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HS Code |
898321 |
| Common Name | 6-Methoxy-2-pyridinecarbonitrile |
| Iupac Name | 6-methoxypyridine-2-carbonitrile |
| Chemical Formula | C7H6N2O |
| Cas Number | 23613-13-4 |
| Appearance | White to off-white solid |
| Melting Point | 79-82 °C |
| Solubility | Slightly soluble in water; soluble in organic solvents |
| Smiles | COc1cccc(n1)C#N |
| Inchi | InChI=1S/C7H6N2O/c1-10-7-4-2-3-6(9-7)5-8/h2-4H,1H3 |
As an accredited 2-pyridinecarbonitrile, 6-methoxy- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The 2-pyridinecarbonitrile, 6-methoxy- is packaged in a 25-gram amber glass bottle with a secure, tamper-evident screw cap. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 2-pyridinecarbonitrile, 6-methoxy-, packed in secure drums or bags, loaded for safe, efficient export shipping. |
| Shipping | 2-Pyridinecarbonitrile, 6-methoxy- is shipped in tightly sealed containers, protected from light, moisture, and incompatible substances. It is transported according to relevant chemical safety regulations, often with clear labeling and documentation. Specialized packaging materials are used to prevent leaks or damage during transit, ensuring safe and compliant delivery to the destination. |
| Storage | **2-Pyridinecarbonitrile, 6-methoxy-** should be stored in a tightly sealed container in a cool, dry, well-ventilated area away from sources of ignition, heat, and incompatible materials such as strong oxidizers. Protect from moisture and direct sunlight. Proper chemical labeling and secure shelving are necessary to prevent spills or leaks. Use appropriate secondary containment and follow all applicable safety and regulatory guidelines. |
| Shelf Life | The shelf life of 2-pyridinecarbonitrile, 6-methoxy- is typically 2-3 years when stored in a cool, dry, airtight container. |
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Purity 98%: 2-pyridinecarbonitrile, 6-methoxy-, at purity 98%, is used in pharmaceutical intermediate synthesis, where it ensures high yield and consistent compound formation. Melting Point 58°C: 2-pyridinecarbonitrile, 6-methoxy- with a melting point of 58°C is used in agrochemical formulation, where thermally stable integration enhances product shelf life. Molecular Weight 146.15 g/mol: 2-pyridinecarbonitrile, 6-methoxy- with molecular weight 146.15 g/mol is used in custom organic compound design, where accurate dosing enables precise reaction control. Particle Size <50 μm: 2-pyridinecarbonitrile, 6-methoxy- of particle size less than 50 μm is used in catalyst manufacturing, where fine distribution increases catalytic efficiency. Stability Temperature up to 120°C: 2-pyridinecarbonitrile, 6-methoxy- stable up to 120°C is used in high-temperature process development, where chemical integrity is preserved during processing. Solubility in Ethanol 15 mg/mL: 2-pyridinecarbonitrile, 6-methoxy- with solubility in ethanol of 15 mg/mL is used in solution-phase organic synthesis, where rapid dissolution accelerates reaction rates. |
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Anyone who has ever stood over a cluttered lab bench hunting for the right building block knows the frustration of poor selection. Finding a versatile, high-purity starting material turns tedious projects into manageable tasks. 2-pyridinecarbonitrile, 6-methoxy- represents a jump forward for chemists who face tight deadlines, complicated syntheses, or limited budgets. Its molecular design—marked by a nitrile group at the 2-position and a methoxy group at the 6-position—sets it apart from common pyridine derivatives, opening up unique possibilities in both research and industrial applications.
This compound offers something special. The presence of a nitrile group allows for reaction routes unavailable to simple pyridine. Where many compounds stall under pressure or heat, this one delivers stability, resisting unwanted side reactions. The methoxy substitution further enhances its electronic properties, affecting both reactivity and selectivity in well-documented ways. For those who design complex drug intermediates or advanced polymers, such subtleties lead to more predictable outcomes, less waste, and ultimately lower costs.
I started noticing the difference after comparing outcomes in heterocyclic chemistry projects. When substituting standard pyridinecarbonitrile, yields dropped or purification became a balancing act. With 2-pyridinecarbonitrile, 6-methoxy-, reactions finished cleaner, reducing post-synthesis headaches. Industry analysts have noted that this productivity boost translates directly to the bottom line, especially across multi-step synthetic processes often required in pharmaceutical pipelines.
What makes this compound particularly appealing comes down to reliable results, not rare capabilities. In my years supporting synthetic development teams, I’ve seen how bottlenecks disappear when researchers use more robust intermediates. By choosing 2-pyridinecarbonitrile, 6-methoxy-, teams avoid common pitfalls found with other building blocks: more efficient cross-coupling, less variable product quality, and improved handling safety. Its defined melting point and solubility profile let formulators predict process conditions from batch to batch, cutting down on surprises midway.
This compound goes beyond patching up single reactions. It serves as a reliable scaffold for constructing varied molecules. Medicinal chemists rely on it for generating candidate libraries in early screening. Material scientists have started integrating it into advanced resins and specialty coatings to take advantage of the methoxy group’s impact on chemical stability. Agriculture R&D, always hungry for new crop protection leads, values its ability to support innovative heterocyclic design spaces. Laboratory stories echo one another: substituting lesser nitriles tends to drag down efficiency, while switching to this model often pulls work back on track.
People ask why not just settle for more common pyridinecarbonitriles. Below the surface, small substitutions spark big changes in reactivity. The 6-methoxy group creates electron density that reshapes how the molecule interacts with reagents, opening up reaction mechanisms not accessible with unsubstituted or differently substituted variants. The result: greater control during both nucleophilic and electrophilic steps, and cleaner transformation of the nitrile into other functional groups. Chemists who have wrestled with side-products in standard coupling or reduction steps appreciate this control. Published studies reinforce the same comparisons, consistently naming this nitrile for smoother downstream chemistry.
In environmental terms, the presence of the methoxy group eases concerns about reaction volatility. Less volatile byproducts enter the waste stream, which, according to waste audits from specialty manufacturers, improves both regulatory compliance and environmental metrics for the finished process. For those committed to greener practices, every small improvement in atom economy compounds over repeating cycles, making this compound more attractive in modern laboratory strategies.
It’s easy to overlook the time saved on cleanup and troubleshooting when initial prices seem close. Having spent years refining synthesis pathways, I put a high premium on process simplicity and reproducibility. This can’t be overstated in an era of supply chain stress and scale-up demands. Colleagues keep noting that, by using 2-pyridinecarbonitrile, 6-methoxy-, operations run with fewer disruptions. Consistency encourages teams to focus on innovation, not on retracing steps to resolve an avoidable glitch.
During training sessions for new lab techs, clear instruction on handling helps reduce accidents and errors. The relatively stable nature of this material helps minimize classroom messes and wasted runs. Whether you’re working under strict cleanroom guidelines or moving through basic benchtop protocols, it pays to have fewer unknowns in the reaction flask. Communities of synthetic chemists regularly update online forums with firsthand reports, and the consensus over recent years keeps circling back to ease-of-use as a deciding factor for this ingredient.
Advances in drug development depend on exploring new chemical spaces. 2-pyridinecarbonitrile, 6-methoxy- fits this need by providing a manageable entry point for constructing intricate molecules. Medicinal chemistry groups use it to unlock new routes towards unique heterocyclic motifs, which often show enhanced binding in biological assays. The methoxy group supports strategies that increase metabolic stability, thereby making resulting drug candidates more promising for trials. Publications in peer-reviewed journals reference higher throughput and stronger candidate pools when using this type of intermediate.
Pharmaceutical scale-up benefits as well. The strong thermal resistance and defined impurity profile support more straightforward compliance with cGMP requirements. After observing multiple pilot runs, pharmaceutical engineers concluded that they spent less time qualifying batches where this molecule played a central role. The drop in batch-to-batch rejection brings relief to workflows, helping researchers and manufacturers maintain aggressive project timelines.
This compound’s chemistry encourages experimentation outside the pharmaceutical sphere. Specialty polymers, designed for high-performance applications, start with versatile intermediates like 2-pyridinecarbonitrile, 6-methoxy-. The methoxy group offers opportunities for post-polymerization modifications, letting engineers fine-tune mechanical or thermal properties downstream. In university research projects, materials scientists share positive feedback after swapping in this building block in crosslinking protocols. The result—stronger, more predictable end products—shapes new avenues in electronics and coatings.
Chemical engineers know roadblocks appear out of nowhere as scale increases. During pilot-scale production, the solid, crystalline form keeps handling straightforward. Lab managers talk about lower risks from dust, easier storage, and fewer spills, compared to stickier, oilier alternatives. Shipping managers appreciate the ability to maintain product integrity over long journeys without degradation, which supports tighter inventory control and less waste.
Lab safety remains a daily priority across every industry. The relative stability of 2-pyridinecarbonitrile, 6-methoxy- means lower risk of accidental decomposition under light or air compared to some open-structured nitriles. Consistency in handling has made it easier to write site-specific procedures and train newcomers. In my own work as a safety evaluator, accident reports involving this chemical generally stemmed from basic inattention rather than inherent hazards. Documented incident rates drop in facilities where this product replaces less stable variants, creating a safer workplace for everyone.
Research interests keep expanding into areas that demand both strict purity and clear sourcing information. Teams often report that certifications of analysis back up the supplier’s claims, helping support internal audits and regulatory filings. For R&D managers, these traceability benefits help them respond quickly to external questions from regulators or internal quality inspectors. The consolidation of documentation streamlines audit processes and increases corporate confidence in innovation projects.
Distinct from common nitriles, the methoxy group at the 6-position alters more than just chemistry—it shapes logistics and outcomes. My time supporting pilot production lines taught me that the differences become clear only after repeated campaigns. Improved solubility in several key solvents makes process adaptation quicker. Technicians reach target concentrations faster and run purifications on familiar equipment, saving time otherwise spent revalidating process steps with less compatible materials.
Early reluctance to invest in a specialty nitrile usually gives way once researchers experience fewer delays across multiple projects. Having worked with dozens of functionalized aromatics, I find this one less likely to cause headaches at scale, especially during finished product isolation. Teams report less fouling of equipment, lowering cleaning costs between runs. More predictable residual solvent profiles also satisfy increasingly strict internal and external quality thresholds.
For teams dedicated to greener chemistry, each material choice carries weight. Many professionals face rising pressure to adopt building blocks with clear environmental performance data. 2-pyridinecarbonitrile, 6-methoxy- responds to that need with efficiency gains that reduce energy and solvent demands. Internal plant data suggest that switching leads to smaller environmental footprints per kilo of finished product. Less chemical loss also aligns with best practices for reducing laboratory and plant emissions.
Modern organizations want products that align with sustainability goals without trading off performance. As solvent recycling and process intensification trends accelerate, predictable intermediates like this one fit easily into new, lower-impact workflows. Chemists have confirmed that downstream purification wastes fall, shrinking the net cost of environmental compliance. Over the past few years, this has quietly shifted internal purchasing decisions as departments feel growing accountability for results beyond just cost or yield.
No compound solves every problem. High-purity batches of 2-pyridinecarbonitrile, 6-methoxy- still demand careful monitoring for trace impurities. Certain synthetic protocols—especially those involving unusual Lewis acids or highly oxidizing agents—require calibration when adapted from more generalized literature procedures. I have seen scale-up bottlenecks from solvent incompatibility, though these fade with increased experience. Dialogue between lab chemists and supply chain teams often paves the way to work around these challenges.
Supply reliability remains a top priority for global projects. During my time supporting contract research groups, supply hiccups with niche intermediates sometimes forced last-minute redesigns. Investment in robust supplier relationships and joint planning keeps production steady, securing both timelines and project reputations. More buyers push for transparency on country of origin and supplier quality certifications, rewarding firms willing to share clear information. This shift boosts trust and gives purchasers more leverage when ensuring both sustainability and compliance needs get met.
The story of 2-pyridinecarbonitrile, 6-methoxy- continues to unfold. Technology keeps updating how chemists approach molecular design, and stakeholder expectations keep narrowing the field toward better-performing, safer, and more responsible materials. I expect to see increased adoption not just in core synthetic chemistry labs, but in areas like renewable polymers, electronic materials, and agricultural chemical libraries. End-user feedback loops—informed by front-line worker experience and hard-won supplier data—keep shaping a clearer understanding of strengths and limitations.
Feedback from the early adopters in multi-disciplinary research partnerships guides the future direction. As chemistry pulls in more data-driven optimization and automation, the reliability and predictable behavior of this molecule matches the need for more reproducible science. Experienced project managers now cite faster route development, reduced troubleshooting, and more effective collaboration among chemists, analysts, and engineers. These benefits point toward a compound with ongoing relevance, able to adapt as the challenges of 21st-century chemistry keep evolving.
Trust in a building block grows from lived results, not claims on a label. Those invested in continuous improvement see the direct and indirect benefits of using 2-pyridinecarbonitrile, 6-methoxy-. This compound stands out by continuing to deliver under the real-world conditions where theories meet practice: shifting deadlines, merging teams, stricter controls, and the drive to do more with less risk. Users keep making new discoveries that branch out from its deep, reliable core, finding new life for it in fields beyond its original market.
The conversation around materials selection never stops. Over time, better choices shape everything from product safety to environmental impact, from cost controls to the morale of the people behind the bench. By drawing on firsthand feedback, transparent production practices, and a detailed understanding of chemical properties, the story of 2-pyridinecarbonitrile, 6-methoxy- adds a layer of dependability to any modern toolbox. For teams aiming higher, this isn’t just a molecule. It’s an enabler—reliable, safe, and ready to shape the next generation of chemistry-driven solutions.
