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HS Code |
300887 |
| Iupac Name | 2-ethoxypyrimidin-4(3H)-one |
| Molecular Formula | C6H8N2O2 |
| Molar Mass | 140.14 g/mol |
| Cas Number | 23987-66-8 |
| Appearance | White to off-white solid |
| Melting Point | 84-86°C |
| Solubility In Water | Slightly soluble |
| Smiles | CCOC1=NC=NC(=O)C1 |
| Inchi | InChI=1S/C6H8N2O2/c1-2-10-6-7-3-4-8-5(6)9/h3-4H,2H2,1H3,(H,8,9) |
As an accredited 4(3H)-Pyrimidinone,2-ethoxy- factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A clear, sealed 100-gram glass bottle labeled "4(3H)-Pyrimidinone, 2-ethoxy-"; hazard symbols and handling instructions displayed. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 4(3H)-Pyrimidinone,2-ethoxy- involves secure, bulk packaging, maximizing space for efficient, safe chemical transport. |
| Shipping | Shipping of **4(3H)-Pyrimidinone, 2-ethoxy-** should comply with all local, national, and international chemical transport regulations. The substance must be properly labeled, securely packaged, and accompanied by a safety data sheet (SDS). Handle and ship only in approved containers, protecting from moisture, heat, and physical damage during transit. |
| Storage | **4(3H)-Pyrimidinone, 2-ethoxy-** should be stored in a tightly sealed container, protected from light, moisture, and incompatible substances. Keep it in a cool, dry, and well-ventilated area, ideally at temperatures below 25°C. Ensure proper labeling and restrict access to trained personnel. Store away from oxidizing agents and sources of ignition. Always follow relevant safety protocols and regulations. |
| Shelf Life | 4(3H)-Pyrimidinone,2-ethoxy- typically has a shelf life of 2-3 years when stored in a cool, dry, and dark place. |
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Purity 98%: 4(3H)-Pyrimidinone,2-ethoxy- with purity 98% is used in pharmaceutical intermediate synthesis, where high chemical yield and product consistency are ensured. Melting Point 152°C: 4(3H)-Pyrimidinone,2-ethoxy- with a melting point of 152°C is used in solid-state formulation development, where stable processing and controlled crystallization are achieved. Particle Size <10 μm: 4(3H)-Pyrimidinone,2-ethoxy- with particle size less than 10 μm is used in fine chemical compounding, where enhanced solubility and homogeneous dispersion are obtained. Stability Temperature up to 110°C: 4(3H)-Pyrimidinone,2-ethoxy- with stability temperature up to 110°C is used in high-temperature reaction processes, where thermal degradation is minimized. Molecular Weight 140.15 g/mol: 4(3H)-Pyrimidinone,2-ethoxy- with molecular weight 140.15 g/mol is used in molecular modeling studies, where accurate stoichiometric calculations and predictable reactivity are facilitated. |
Competitive 4(3H)-Pyrimidinone,2-ethoxy- 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@bouling-chem.com.
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Tel: +8615371019725
Email: sales7@bouling-chem.com
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Standing in the production halls, we see our team moving through every shift with the persistent aim to push quality beyond assumptions. 4(3H)-Pyrimidinone,2-ethoxy- is not just another catalogue entry—it shapes up as a result of targeted synthesis using raw materials sourced for consistency and stability. Our chemists control every step, keeping the focus on process reproducibility and adjusting conditions when small changes in temperature or moisture content in precursors suggest a need. The end result offers performance and traceability unmatched by intermediaries or bulk blenders.
Each reaction batch has years of know-how behind it. We track input purity, catalyst sources, and solvent exchange cycles, maintaining logs that go decades back for regulatory demands and customer inquiries. Lab technicians announce a new lot number only after analysis in our own labs, where spectra and assays match the strict numbers we know the market expects. Customers tell us they notice these high standards downstream: manufacturing plant managers report less downtime from cleaning and fewer off-spec outcomes.
Most downstream customers using 4(3H)-Pyrimidinone,2-ethoxy- do not just request generic purity—they count on tight impurity controls. Over the years, we fielded samples with minute color differences, trace non-polar byproducts, or fluctuating melting points, all flagged by partners whose QC teams know the cost of failed lots or requalifications. Drug and agrochemical plants do not have time for guesswork or out-of-specification surprises.
We focus these concerns into our product framework. Melting point, purity (using HPLC, NMR, and GC), water content, and residual solvents are all measured batch by batch. Our raw pyrimidinone matches published pharmaceutical standards, and input references go to the earliest shipment. Production runs track each drum and order so we can explain every deviation and how it got fixed. This brings peace of mind to both pilot-scale chemists and commercial formulators who look for substances that behave the same, month after month.
End users notice that our process keeps contaminant fingerprinting visible. For applications in synthetic pesticide intermediates or heterocyclic pharmaceutical building blocks, this reliability means less troubleshooting, fewer chromatographic purifications, and—most importantly—no shutdowns for “unexpected behavior.” Many of our returning clients started with small R&D drums, moved to multi-ton containers, and told us bluntly that the clarity of our analytical certifications influenced their choice. Our manufacturing records give these customers confidence that batches run on schedule and to spec.
Distributors may quote lead times or batch flexibility, but our direct dialogue with customers uncovers challenges early and helps us resolve them for everyone. A few years ago, a major pharmaceutical player sent us repeated queries about crystal habit modification—they worried about downstream filtration times. We adjusted certain seeding protocols, logged those changes, and found a morphology that passed their requirements. That solution made its way into the standard process, and similar requests now get processed much faster.
Another example: some clients encountered challenges scaling up high-reaction-load processes. They asked if upstream solvent residues or trace elemental impurities impacted yield. We investigated, adjusted our purification stages, and reported side-by-side analysis on before-and-after samples. Customers said these direct answers let their chemists spend less time identifying root causes, referencing published spectral fingerprints, and documenting compliance for regulatory filings.
Knowledge only builds in conversations. This two-way feedback shows as improved yields on customer lines. We retain those lessons and translate them into routine process improvements—not just rare accommodations for one order, but industry-facing upgrades.
Many chemical products with similar names can mislead buyers about equivalence. Our 4(3H)-Pyrimidinone,2-ethoxy- is not a commodity material with variable side fractions or uncertain origins. Subtle differences in alkylation step, solvent stripping, or crystal isolation can change impurity profile, powder flow, and even reaction color in downstream applications. We routinely test against marketplace competitors’ material, comparing spectral signatures, melting range tightness, and microtrace composition.
Years ago, a partner showed us two different “equivalent” sources. The alternative produced anomalous color changes after just a few days in storage, impacting their end formulations’ storage stability. We traced it to stabilized by-product content that our processes filter out. Since then, large-volume buyers ask us to show side-by-side stability data before introducing this product to new plants. Our lot traceability and hands-on sample testing stand up to that scrutiny—if a competitor claims equivalence, we give chemists direct dossiers and encourage their own analytical cross-checks.
Execution starts with raw inputs ordered in bulk from qualified sources. We run incoming material identity checks, then use closed-system reactors monitored for temperature fluctuation and cross-contamination. Between steps, we purge and vacuum dry all intermediate vessels. Onsite staff see each stage: staff samples at the midpoint, tests for complete conversion, and only moves to the next step when tight requirements match target specs.
Some clients request extra documentation, others ask to inspect or audit our plant in person—our doors are open to their technical teams. Granular process control gives more confidence than batch blending or repackaging. Yield trackers and data historians back up claims, and internal audits check everything before shipping. Finished goods get segregated under stable temperature until analytical realizes full release, eliminating out-of-window storage time.
We see these efforts pay off. Recurring buyers report less batch-to-batch troubleshooting and less need to revalidate downstream syntheses. Our pre-shipment inspection protocol leaves customers with assurance—no leaks, mislabeled drums, or ancient warehouse residue, since every container clearly tracks its ship date and supporting specifications.
Our technical support line comes from hands-on operations staff, not a customer service FAQ. Any time a chemist calls with a question about reactivity or application compatibility, we start with production notes and batch history. This focus helps diverse end users, whether they are pharmaceutical research labs optimizing a lead synthetic step or agrochemical manufacturers aiming to improve reaction economy.
Over the past decade, 4(3H)-Pyrimidinone,2-ethoxy- established a reliable presence in pyrazole and triazine derivative production. Not all plant operators have the same needs. We supply advice from our own experience: small R&D batches, pilot-scale optimization, or commercial multi-ton demands. If a research team wants compatibility checks with chlorination sequences, we review our historical data and sometimes tweak our own process for specific impurity sensitivity.
Our product meets more than generic use cases. Some customers request modified wetting profiles, others want support in granulation and blending downstream. We discuss and tailor process points to smooth out these differences. This approach helps partners scale processes, align with changing regulatory expectations, and build recipes that avoid unnecessary intermediate purifications. The resulting process economics and time savings pass directly to customers seeking to innovate.
Pharmaceuticals, crop protection, and specialty chemical manufacturers deal with regulatory scrutiny and time pressure. We support those realities with detailed product declarations, integrated traceability, and immediate documentation. Application engineers have told us they choose our material thanks to our transparent origin records and willingness to provide comprehensive impurity profiles, which helps finish formulations on time and meet market release schedules.
Product safety goes beyond regulatory boxes. Our plant tracks all process changes by lot, and we issue notification if any planned adjustment could affect compliance or outcome. Regulatory inspections often call for real process records—these come from the same staff maintaining the reactors. Plant operators and technical teams know exactly which version of our product reached their lines, making audits and process validation more straightforward and less adversarial.
Even when customers request new application testing or unexpected certificate details, we answer with our own manufacturing log, maintained in the plant, not in a sales office. This transparent, accessible record gives process managers confidence to scale up or adjust regulatory dossiers without last-minute hunting for proprietary answers.
The market offers countless chemicals with similar sounding names or generic purity grades. We focus on crystalline state, impurity fingerprint, and storage behavior—observable differences that can make or break a process at scale. Buyers comment on the openness and speed with which we handle sample analysis and explain differences from other sources. People in labs tell us they see a difference in ease of filtration, downstream solubility in typical process solvents, and the absence of unanticipated side effects during reaction scale-up.
A common pain point for new customers comes when they try switching suppliers. Apparent substitutes bring unexpected costs—extra time refining process parameters, running additional spectral checks, or purifying more aggressively after reactions. Some users see unexpected color instability, off-odors, or patent infringement headaches tied to questionable upstream supply. Our product’s provenance and in-house manufacturing pathway take away these worries. We show customers every detail, ensuring clear differentiation and zero doubt about what goes into their syntheses.
Over the years, scale-up support became our main differentiator. Many intermediaries offer only catalogue shipping—little engagement beyond a tracking number. By contrast, our technical staff advise on drum sizes, handling, and application-specific handling. We provide guided documentation and log shipping temperatures for sensitive orders, so distribution partners and contract manufacturers keep quality locked down.
Our plant’s ability to flex production volume helps customers outpace schedule spikes. Whether a pilot project demands grams or a commercial rollout grows to metric tons, our reactors support the whole curve, keeping product characteristics locked. Customers gain an upstream partner, not just a label printer or supplier of undifferentiated powder. This stability eliminates worries around process upsets, timeline disruptions, or shipment inconsistencies.
Supply chain interruptions test every manufacturer's resilience. We built long-term relationships with upstream suppliers, maintain inventories on site, and regularly sustain uninterrupted multi-batch runs. Schedulers in downstream plants value certainty—they look for partners who can answer “yes” to questions about next month’s shipout, even in volatile markets or under new regulatory regimes.
Innovation teams at our customer facilities push for better atom economy, reduced waste, and sharper selectivity. We join those efforts by providing not only a consistent product but also detailed historical records enabling process optimization. Some customers reduced their solvent use and waste disposal costs by tuning their reactions based on our product's specific impurity profile. Others identified cost savings in process energy use after consultation with our technical group.
Sustainability gains arise from process transparency and predictable outcomes. By knowing exactly what impurities are present and how our product behaves under a range of process conditions, customers save not only on rework and material loss but on environmental impact. Plant managers aiming for green chemistry targets appreciate clear documentation and batch reproducibility because these milestones support outside audits and sustainability certification.
We keep listening to industry needs, adjusting production methods when cleaner technologies or greener reagents become viable. Environmental regulations prompt us to refine waste handling, solvent recoveries, and reaction optimization. As regulations tighten and priorities shift, these changes ripple into faster cycle times, fewer scrap batches, and lower risk.
Customer expectations evolve. Past experience taught us that sudden spikes in regulatory scrutiny, patent shifts, or raw material market swings can challenge even seasoned chemical producers. Manufacturers who manage all links in the supply chain—sourcing, synthesis, refining, packaging, and logistics—own the agility to address these new demands quickly.
Keeping real data and people at the ready, we move fast. Onsite analytical capacity gives us daily process diagnostics, full reporting mid-production, and immediate feedback if any deviation signals risk. This means our product can adjust in the span of a week, not a quarter, when customers seek renewals, new certifications, or market expansions.
We work to anticipate new application spaces as well. Touchpoint meetings with leading research chemists or industry consortia direct us to preempt supply needs and tweak certification offerings. These cycles of feedback and direct adjustment shorten project timelines for our customers and minimize disruption, allowing chemical innovation to meet shifting societal and market demands.
Many chemicals compete for space in research, production, and commercial formulations. Direct-from-manufacturer sourcing with 4(3H)-Pyrimidinone,2-ethoxy- means more than a supply contract. It is a guarantee built from process control, ongoing dialogue, and clarity that take years to instill but seconds to recognize in lab, plant, or market results. We keep learning from customers, continuously growing our approach so that today’s product addresses both immediate commercial needs and tomorrow’s innovative challenges.
Concrete quality, transparency in process, and a technical support team with actual hands-on experience drive better outcomes for every batch in every plant. We will keep aligning our production and people to the future, giving every customer access to solutions grounded in facts, not shortcuts.
