|
HS Code |
343344 |
| Product Name | 2-Methoxymethyl pyridine |
| Cas Number | 3430-13-5 |
| Molecular Formula | C7H9NO |
| Molecular Weight | 123.15 g/mol |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | 197-199 °C |
| Density | 1.085 g/cm3 |
| Flash Point | 82 °C |
| Solubility | Soluble in organic solvents |
| Purity | Typically ≥98% |
| Storage Conditions | Store in a cool, dry, well-ventilated place |
| Smiles | COCNC1=CC=CC=N1 |
As an accredited 2-METHOXYMETHYL PYRIDINE 2-METHOXYMETHYL PYRIDINE factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 250g amber glass bottle with secure screw cap; labeled with product name, chemical formula, hazard warnings, and manufacturer details. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 2-Methoxymethyl Pyridine: typically packed in UN-approved drums, 16–18 metric tons per 20-foot container. |
| Shipping | 2-Methoxymethyl pyridine is shipped in tightly sealed containers, protected from moisture and light. It is transported as a hazardous chemical, requiring appropriate labeling and documentation in compliance with local and international regulations. Ensure proper handling, storage at room temperature, and use of personal protective equipment during shipping and delivery to prevent leaks or exposure. |
| Storage | **2-Methoxymethyl pyridine** should be stored in a cool, dry, and well-ventilated area, away from sources of ignition and direct sunlight. Keep the container tightly closed when not in use and store it in a suitable chemical-resistant container. Avoid contact with oxidizing agents and acids. Ensure appropriate spill containment measures and follow all local regulations for storage of hazardous chemicals. |
| Shelf Life | 2-Methoxymethyl pyridine has a typical shelf life of 12–24 months when stored in a cool, dry, tightly sealed container. |
|
Purity 99%: 2-METHOXYMETHYL PYRIDINE 2-METHOXYMETHYL PYRIDINE with purity 99% is used in pharmaceutical intermediate synthesis, where high chemical purity ensures minimal byproduct formation. Molecular Weight 137.17 g/mol: 2-METHOXYMETHYL PYRIDINE 2-METHOXYMETHYL PYRIDINE featuring molecular weight 137.17 g/mol is used in medicinal chemistry research, where precise molecular mass facilitates accurate compound formulation. Boiling Point 195°C: 2-METHOXYMETHYL PYRIDINE 2-METHOXYMETHYL PYRIDINE with boiling point 195°C is used in solvent production, where thermal stability under reflux enhances process safety and efficiency. Density 1.08 g/cm³: 2-METHOXYMETHYL PYRIDINE 2-METHOXYMETHYL PYRIDINE at density 1.08 g/cm³ is used in agrochemical formulation, where consistent density allows homogeneous blending. Stability Temperature 25°C: 2-METHOXYMETHYL PYRIDINE 2-METHOXYMETHYL PYRIDINE stable at 25°C is used in analytical laboratories, where ambient-temperature stability supports accurate experimental results. Refractive Index 1.523: 2-METHOXYMETHYL PYRIDINE 2-METHOXYMETHYL PYRIDINE with refractive index 1.523 is used in optical material research, where precise refractive properties improve analytical measurement. Melting Point -10°C: 2-METHOXYMETHYL PYRIDINE 2-METHOXYMETHYL PYRIDINE with melting point -10°C is used in low-temperature reaction systems, where low solidification point ensures handling under diverse thermal conditions. Water Content <0.5%: 2-METHOXYMETHYL PYRIDINE 2-METHOXYMETHYL PYRIDINE with water content below 0.5% is used in moisture-sensitive syntheses, where minimal moisture prevents unwanted hydrolysis. |
Competitive 2-METHOXYMETHYL PYRIDINE 2-METHOXYMETHYL PYRIDINE 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.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: sales7@boxa-chem.com
Flexible payment, competitive price, premium service - Inquire now!
Inside the production line, days revolve around refining compounds that drive forward both research and industry. Among the catalog, 2-Methoxymethyl Pyridine stands out. The process begins by sourcing high-purity precursors, continues through complex reaction steps, and ends in a product that’s more than just a chemical formula — it’s a solution forged by meticulous design. Our direct connection with this compound provides insight that goes beyond a spec sheet. Knowledge has grown with every batch, each distillation, every inquiry from partners crafting pharmaceuticals, and every innovation in specialty materials.
2-Methoxymethyl Pyridine brings real value to laboratories and production floors chasing performance or reproducibility. What we see most often with this molecule is its utility as a building block for next-stage synthesis. The methoxymethyl group on the ring increases solubility in a range of organic solvents, making workup and isolation more straightforward for technicians. From the chemical engineer dialing in kinetics, to the research scientist testing ligands, these small advantages matter.
Our product typically follows a consistent physical profile: a colorless to pale yellow liquid, low boiling, and with a purity that meets or surpasses 99%. These aren’t arbitrary numbers chosen in a vacuum — they reflect continual investment in column purification, analytical validation, and feedback from our customers. The priority always stays with minimizing trace contamination that could interfere downstream, whether you’re coupling the compound, alkylating, or pushing it into pharmaceutical intermediates.
We approach specifications not just as targets, but daily challenges in every cycle. A process engineered to maximize both throughput and purity means fewer shutdowns for decontamination and less wasted off-spec product. Our team monitors every lot, using NMR, HPLC, and GC techniques to quantify quality and detect residual impurities — not just pyridine core variants or unreacted methoxymethyl donors, but also minor side-products that can cause headaches later on.
We never assume that “good enough” meets the industry need. Having handled customer complaints and recalls elsewhere in the supply chain, the value of reliable batch records and traceable analytical data stands out. Our technical team maintains an archive of analytical results and synthetic conditions, so a question about solubility, boiling point, or by-products receives a precise answer, not a vague assurance. This approach helps others build trust in their own product pipelines.
Most incoming orders for 2-Methoxymethyl Pyridine trace back to sectors requiring functionalized heterocycles. Pharmaceutical companies use the compound as a precursor for antihypertensive drugs, antiviral candidates, or CNS-active molecules. Custom synthesis shops leverage the methoxymethyl group for selective derivatization — a protected site for future transformations, or a platform to introduce chirality in enantioselective pathways.
In agrochemical development, research teams look for building blocks that can undergo selective cross-coupling. This molecule provides flexible reactivity and compatibility with a range of metal catalysts. As new combinatorial methods and library syntheses emerge, requests for compounds with well-characterized methyl, methoxymethyl, or similar groups have increased. The compound’s reactivity makes it a launchpad for functionalized materials and specialty polymers, too, and direct conversations with formulators inform us where additional purification or documentation could enhance their workflow.
Producing tons of intermediate materials, some complexities can’t be appreciated from a data sheet alone. One real-world lesson comes from solvent choice — 2-Methoxymethyl Pyridine performs best when kept in the right container materials and handled under dry conditions. Operations discovered that trace water yielded side reactions in shipping, so in-house protocols now keep humidity tight and packaging inert.
Shipping quality solidifies when we check material on both ends. Repeated feedback from clients has reinforced the importance of consistent viscosity, color, and odor profile. Small off-notes in smell, a minor haze, or an unexpected tinge in color often point to subtle process changes — maybe a shift in reaction temperature, or aging in storage. Lessons like these reshape manufacturing every year, influencing everything from fine-tuned distillation parameters to supply chain planning.
Pyridine derivatives cover a wide turf. Some bear halogen or methyl groups, others go to extremes with complex side chains. The addition of a methoxymethyl group in the 2-position makes this molecule unique among close analogs. Compared to simple 2-methylpyridine, the methoxymethyl function alters polarity and steric profile. This effect can enhance or hinder reactions depending on goals — in alkylation or nucleophilic substitution, the electron-donating nature of the group finely tunes reactivity.
Manufacturing teams have witnessed cases where a basic 2-alkylpyridine failed in synthesis, but the methoxymethyl version unlocked cleaner yields or higher selectivity. The group also serves as a convenient removable mask, used for protection in multi-stage processes. The versatility shows in repeated orders from customers scaling a variety of molecular scaffolds, who report more reliable conversion and easier work-up with this derivative compared to those with more rigid or less-soluble functionalities.
Comparisons to 2-benzyloxymethyl pyridine or other ethers reveal further differences. The methoxymethyl group imparts a balance: robust enough to endure typical processing, yet removable under the right conditions. This feature shortens synthetic routes and clears up purification for final-stage compounds. We often support partners as they switch from slower or less selective alternatives, using practical data and hands-on process advice gleaned from years at the reactor.
Direct dialogue with researchers using 2-Methoxymethyl Pyridine keeps quality control grounded. Several times per year, partners run trial batches or pilot-scale projects that call for troubleshooting. Requests range from improving storage stability to helping select compatible solvents for large-batch reactions. Time spent listening to these challenges pays off, revealing small process tweaks that deliver smoother scale-up, cleaner profiles, or faster downstream conversion.
A standout memory involves a customer who faced dramatic batch-to-batch variance with a third-party supplier. They approached our team after failed API synthesis meant weeks of troubleshooting and wasted material. By providing thorough characterization and process transparency, our factory helped them regain predictability and speed in their manufacturing chain. Over time, mutual trust allowed us to adjust production schedules, provide technical notes, and include stability testing by default, because we understood how it all connected to a partner’s end goals.
Continuous improvement defines daily work. Meeting new environmental and safety standards shapes both process and product, since these regulations can change year by year. Handling pyridine compounds demands care — ensuring low residual solvents, maintaining closed systems, monitoring emissions. Manufacturing experience shows that the easiest process on paper can require persistent updates in the plant.
Product customization grows from direct customer input. Some prefer specification of water content down to a single decimal point, others need detailed impurity profiles. We respond by refining synthesis, investing in upgraded dryers, developing more scalable routes, and validating stability in real storage environments. Our R&D, arm-in-arm with the quality team, steers new product forms or packaging options to meet these evolving demands.
Access to the molecule depends on the production team’s coordination. Procurement lines must deliver raw materials of tightest purity, operators run distillation systems around the clock, and analysts check every drum before shipment. Decades of combined experience across shifts make it possible to anticipate seasonal supply swings or identify supplier drift — tracking trends that a static distribution layer often misses.
On the regulatory side, the stakes run high. Many sectors, from pharma to specialty polymer manufacturing, expect transparent documentation and rigorous certification. We maintain traceable batch documentation, Safety Data Sheets reflecting the actual manufacturing route, and proof of compliance with REACH or other regulatory bodies. Third-party audits keep both operators and supervisors sharp, reinforcing a culture that connects documentation with accountability on the factory floor.
Every instrument calibration, every check of purity, and each revision of our protocol stems from real QC and compliance challenges. Once, a small residual solvent level crept above target in an outgoing batch. Lessons learned led us to reinforce pre-shipment testing and batch segregation, so performance stayed consistent and regulators received complete, factual paperwork. Ties between on-the-ground operations and quality documentation ensure standards translate to real-world outcomes for customers.
Transitioning from lab to production scales reveals gaps that spreadsheets rarely catch. Reaction exotherms behave differently in a thousand-liter reactor than on the bench. Cooling needs escalate and by-product formation changes. We’ve solved heat transfer issues by breaking down process steps, investing in newer heat exchangers, and improving agitation speeds during key additions. These lessons, learned through hands-on failures and root cause analysis, support partners trying to avoid costly downtime or unexpected waste.
Another pain point crops up during filtration and purification. Solubility profiles look perfect in a 100 mL flask, but viscous emulsions can paralyze a large-scale filter. Operators have responded by developing incremental additions, vacuum tweaks, and solvent rinses to resolve issues quickly. Our experience has led to smoother operations and faster turnarounds for customers, since we aren’t stuck waiting weeks to analyze the root of new processing hurdles.
The most valuable improvements often originate from those actually using the chemical. End users in synthesis and formulation contact us through technical support, eager or sometimes frustrated, seeking advice on everything from handling procedures to compatibility with specialized glassware or automation. Each question is an opportunity to tighten production, documentation, or support. If a batch crystallizes unexpectedly, or an off-odor appears in storage, that report triggers an immediate review of plant practices.
We see the compound both as a product and as a participant in a much larger ecosystem. Formulators share insights on product shelf life and performance in their unique setups, which drives us to revisit drying protocols or packaging seal quality. One customer once discovered that transport through humid climates slightly altered the compound’s reactivity, leading to swift changes in our own logistics and storage instructions.
Responsible production roots itself in everyday practice. We load every drum with attention to detail, knowing contamination or improper handling can block a customer’s whole process. Operator training cycles often highlight case studies — a small deviation in temperature or a missed filtration step can ripple through production, so responsibility isn’t just a word here, it’s tied to every action on the floor.
As sustainability expectations increase, chemical plants must adapt. Energy efficiency programs decrease waste heat and emissions, but they also create process engineering challenges. Sourcing greener solvents, selecting suppliers with strong transparency, and reducing process steps all come from efforts grounded in practical experience. Each new production run adapts to lessons learned from previous cycles, and customer needs push for cleaner, safer, more sustainable product.
Supply chain continuity keeps product flowing, but hiccups occur. We have seen raw material shortages, interrupted shipping, and new customs hurdles that threatened to slow output. By investing in local storage, qualifying backup vendors, and investing in tracking for every shipment, the supply chain becomes more robust. Communication between production, procurement, and logistics unearths problems before they land in a customer’s hands.
Security and compliance mean both product quality and transparency in sourcing. The plant maintains full traceability for inbound and outbound material, and adjusts shipment packaging to meet different regulatory or customer-specific requests. The result is more reliable on-time delivery and peace of mind for partners further downstream — an often-overlooked value until things go wrong.
Continuous production and ongoing customer feedback turn a chemical like 2-Methoxymethyl Pyridine from a commodity into a partnership tool. Every specification, process tweak, and technical problem solved adds up to smoother operations for those who depend on consistent material. Years standing alongside the product have taught us that no process or batch ever stays “finished;” there’s always another chance to learn, improve, and support those building the next wave of chemical innovation.
The compound’s history within our plant isn’t just measured in liters shipped or certificates generated, but in real relationships with recipients. Unlike intermediaries or marketers, direct manufacturers live every stage of production, bear the brunt of any shortfall, and take pride in every successful reaction a client achieves. For 2-Methoxymethyl Pyridine, and for much of chemical manufacturing, that perspective makes all the difference.
