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All Right Reserved
|
HS Code |
703192 |
| Iupac Name | N-(4-Ethoxycarbonylphenyl)-N'-methyl-N'-phenylformamidine |
| Molecular Formula | C17H18N2O2 |
| Molecular Weight | 282.34 g/mol |
| Cas Number | 119406-39-6 |
| Appearance | Pale yellow solid |
| Melting Point | 105-108°C |
| Solubility | Soluble in organic solvents such as dichloromethane, chloroform, and ethyl acetate |
| Smiles | CCOC(=O)C1=CC=C(NC(=N(C)C2=CC=CC=C2)H)C=C1 |
| Inchi | InChI=1S/C17H18N2O2/c1-3-21-17(20)14-8-10-15(11-9-14)19-16(18-2)13-6-4-5-7-12-13/h4-12H,3H2,1-2H3,(H,19,18) |
| Storage Conditions | Keep in a cool, dry place away from light |
As an accredited N-(4-Ethoxycarbonylphenyl)-N'-Methyl-N'-Phenylformamidine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Sealed in a 25-gram amber glass bottle with a tamper-evident cap, labeled with chemical name, hazard symbols, and lot number. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for N-(4-Ethoxycarbonylphenyl)-N'-Methyl-N'-Phenylformamidine involves secure drum/box packing, moisture protection, and palletization for safe bulk transport. |
| Shipping | The chemical N-(4-Ethoxycarbonylphenyl)-N'-Methyl-N'-Phenylformamidine should be shipped in a tightly sealed, labeled container, protected from light and moisture. Use secondary containment, and pack with sufficient cushioning. Comply with relevant regulations for hazardous materials, ensuring documentation and handling procedures meet safety standards during transit. Store at recommended temperature upon arrival. |
| Storage | N-(4-Ethoxycarbonylphenyl)-N'-Methyl-N'-Phenylformamidine should be stored in a cool, dry, and well-ventilated area, away from direct sunlight and incompatible substances such as strong oxidizing agents. Keep the container tightly closed to prevent moisture absorption and contamination. Store at room temperature or as specified by the manufacturer, and handle under appropriate safety conditions, including wearing gloves and eye protection. |
| Shelf Life | Shelf life: Store **N-(4-Ethoxycarbonylphenyl)-N'-Methyl-N'-Phenylformamidine** in a cool, dry place; stable for at least 2 years. |
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Our team has been engaged in the development and production of N-(4-Ethoxycarbonylphenyl)-N'-Methyl-N'-Phenylformamidine for a number of years. Through hands-on work with this material, we see first-hand where it stands apart in the specialty chemicals segment. It was not chosen lightly for our portfolio; we only bring in products we know we can manufacture consistently and with high purity. This compound plays a unique role in organic synthesis, offering flexibility for further modifications and downstream applications, especially for those working in fine chemical production or developing specialty intermediates.
Our production process is grounded in reaction control science. Small changes in process timing, temperature, and cleanup steps directly impact the quality of the end product. Our batches regularly achieve purity levels suited for demanding synthesis environments. By tuning reactivity and solubility, the structure delivers straightforward integration into multistep syntheses. Our customers report high reliability whether they are focused on agrochemical precursors, pharmaceutical intermediates, or novel material design.
This material takes the form of a solid at room temperature. We have routinely observed a stable, free-flowing powder after purification and drying—a manageable raw input for scaling reactions. Batch consistency matters to us, as uncontrolled crystallization or moisture pick-up impacts downstream performance. Time spent on pilot production transfers has shown that careful solvent choice during the crystallization phase drastically reduces unwanted polymorphs and keeps the melting range tight from lot to lot.
Stability, even on extended transit, marks a big improvement over some similar amidine compounds. We subjected finished product to accelerated aging, reproducing humid storage and fluctuating shipping temperatures. Afterward, key quality indicators such as moisture uptake and formamide decomposition products tested far below concern limits. End users often mention this compound blends cleanly into solution for preparative steps without traces of yellowing or clumping.
Researchers and process chemists tell us they rely on N-(4-Ethoxycarbonylphenyl)-N'-Methyl-N'-Phenylformamidine because it fits with their established synthetic toolboxes. This amidine structure supports development of a range of target molecules through coupling, protection, or as a key intermediate in carbon-nitrogen bond formations. Our team interacts with customers on routine troubleshooting—adjusting solvent choices, discussing reaction conditions, or identifying byproducts. Real-world feedback brings our quality initiatives into sharper focus.
The ethoxycarbonyl protective group on the para position of the phenyl ring adds value for controlled reactivity, diverting possible side reactions and supporting selectivity during multistep operations. This often proves essential for those running complex, highly tuned syntheses or wanting to avoid unexpected cross-reactivity. The presence of the methyl and phenyl on the N' positions makes this molecule distinct from simple symmetrical amidines. They introduce a steric and electronic profile that influences everything from crystallization to dissolution in organic media.
Many newer synthetic targets, such as heterocyclic frameworks or advanced dyes, use this amidine as a starting block. We’ve collaborated with several labs who discovered that using high-purity material removes variables when scaling from bench to pilot scale. Every production run we execute includes extensive analytical work—both routine chromatography and modern NMR analysis—so we can assure users of the absence of residual starting materials and trace contaminants.
Laboratories and plants increasingly prioritize source reliability, not just minimum specification. During pilot runs years ago, our own chemists struggled with a batch from a market supplier showing unexplained color and inconsistent melting point. By contrast, our in-house controls—drying protocols, filtration steps, and final sieving—help avoid product variability that not only slows work, but sometimes triggers costly re-runs.
Our own trials have shown that “just-good-enough” product creates process drift in multi-step syntheses. A high-purity batch knocks down background reactions during sensitive amidine condensation or acylation. By investing in both in-line and final analytical controls, we saw reject rates in partner pilot plants drop off. Labs often share that a defined impurity profile means more predictable downstream recoveries and less optimization time.
Chemical manufacturers face raw material challenges daily, especially as customers demand more documentation and reproducibility. We prepare every batch of N-(4-Ethoxycarbonylphenyl)-N'-Methyl-N'-Phenylformamidine with traceability. Analytical documentation accompanies every shipment, and we provide users with access to in-house technical liaisons who can speak the language of synthesis and product stewardship based on actual batch history, not generic standards statements.
Our business model relies on direct manufacturing. It’s easy to overlook this distinction until you run into the limitations of a trading source. On average, brokers in the chemical supply chain introduce longer lead times, inconsistent lot sources, and gaps in technical knowledge. Since we run the reactors, pack the product, and sign off the batch paperwork ourselves, we control response time and feedback cycles.
Firsthand experience with each production scale-up means our technical and plant teams know every process variable. In meetings with project leads from major chemical companies, we’ve shared lessons from actual campaigns—how minor filtration tweaks, for example, shift product purity and filter flow rates. This firsthand perspective helps customers avoid common pitfalls that crop up in high-throughput manufacturing or process design. We also routinely review and revise our process protocols based on emerging best practices and regulatory findings.
Direct manufacturing means we provide users with lot-specific guidance, from ideal storage and handling to best methods for dissolving or mixing the product. Our warehouse frequently ships to multiple continents in a given week. After supporting projects from laboratory research through scale-up, our product managers carry feedback on packaging, hazards, and application-specific concerns back into our production review cycles. Over time, this loop of manufacturing, feedback, and improvement leads to a robust supply chain that delivers on spec, on time.
N-(4-Ethoxycarbonylphenyl)-N'-Methyl-N'-Phenylformamidine draws comparison from chemists with structurally similar amidines and protected intermediates. Some commonly supplied amidines lack the layered substitution, such as simple symmetrical N,N'-diphenyl or N,N'-dimethyl analogs. Often, these simpler compounds cannot offer the same level of reactivity control when incorporated into multistep syntheses.
In cases where the ethoxycarbonyl substitution is absent, users notice a greater tendency for cross-reactivity, sometimes leading to yield losses or side product formation downstream. The additional complexity of our compound offers chemists an extra handle—both sterically and electronically—for achieving selectivity, especially when managing delicate intermediates or constructing complex aromatic frameworks.
Solubility properties also set our material apart. Through our own bench tests, we’ve observed that this amidine provides higher solubility in many common polar aprotic solvents than less substituted analogs. This promotes smoother transitions between stages during material-intensive projects, minimizing recovery headaches and solvent compatibility surprises.
Market feedback confirms that downstream purification runs cleaner, especially compared with products from bulk commodity suppliers. Our commitment to regular analytical chemistry means fewer instances of unexpected color bodies or residual byproducts, which otherwise complicate separation steps and pose analytical challenges in GMP settings. We routinely encourage collaborators to benchmark our material against alternatives in real process conditions.
Chemical synthesis places high expectations on intermediate materials. Challenges arise from uneven supplier quality, shifting regulatory environments, and market-driven changes in raw material sourcing. In our experience, by owning the manufacturing process, challenges can be addressed before material leaves the plant. Instead of chasing documents from upstream brokers, our teams generate and check each certificate of analysis from our own labs.
A steady supply of high-purity amidines matters most during scale-ups or regulatory audits. Our approach draws on lessons from both fine chemical manufacturing and the agriscience sector, where specifications may tighten at any point during a project. Results from our process validation campaigns get shared directly with customer quality teams. This builds confidence, avoids project stalls, and keeps the chain of custody clear.
Years of production experience with specialty aromatic compounds taught us to flag even minor deviations. For instance, an unnoticed trace impurity can affect color, crystal habit, or even downstream reactivity in paired reactions, adding cost in both time and resource allocation. Our current quality control standards evolved from incidents early on—such as mixed-crystal contamination that slowed a pilot run—pushing new attention into every process tweak.
By maintaining in-house knowledge and technical records, our staff can quickly spot and trace sources of any irregularity, minimizing disruption and keeping projects on schedule. Customer leads often draw from our in-plant experience, rather than generic product profiles, which helps meet their unique application challenges.
Chemical manufacturers like us operate in a fast-changing landscape. Compliance concerns, emerging environmental regulations, and evolving technical standards create a dynamic backdrop. Our approach to N-(4-Ethoxycarbonylphenyl)-N'-Methyl-N'-Phenylformamidine reinforces our broader commitment to transparency, ongoing process control updates, and supporting sustainable chemistry initiatives.
We regularly consult with customer project teams on solvent handling, waste management, and documentation transfer. Over the years, we’ve adapted our own practices to support more environmentally conscious manufacturing. For example, we’re progressing on solvent reuse routines and minimizing single-use plastics in packaging, based on direct customer feedback and internal sustainability goals.
Where customer teams require regulatory documentation or green chemistry roadmaps, we help bridge information gaps by sharing in-plant process details and encouraging co-development of novel routes. This hands-on, real-world approach grows more valuable as regulatory and due diligence pressures mount within global project teams. The details we share from our own operational history provide the assurance that comes from real-world use, not just certificate printouts.
We see collaboration and information transparency as essential. Direct manufacturing experience supports these goals far better than a trading model. By working side-by-side with customers, project managers, and sourcing partners, we’re able to respond quickly to changing needs with more reliable solutions.
We devote time each year to updating and refining both manufacturing protocols and customer support materials, prioritizing clarity and factual accuracy. Every revision draws directly from plant-level experiences. This allows our product support staff to provide guidance that reflects the realities of raw material variability, packaging innovations, and best practices learned from years of cross-functional production teams.
For N-(4-Ethoxycarbonylphenyl)-N'-Methyl-N'-Phenylformamidine, our QC team’s close involvement at every stage helps us deliver a robust and trustworthy product. This means more than checking boxes or passing laboratory benchmarks. Our staff actively participates in delivering customer-specific information that reflects lot-level differences—helping chemists understand how subtle experimental variables might interact with the characteristics of a given supply batch.
A steady record of regulatory compliance and supply chain integrity also informs our standards. This translates into regular supply chain audits and internal process reviews, informed by both technical literature and feedback from customers working at the cutting edge of their respective fields. Our presence at technical conferences and in working groups shapes how our products evolve to better meet the requirements of the modern laboratory and production environment.
All communication on product changes, process adaptions, and new analytical methods flows directly from in-house R&D and plant operations. We see candor and accessibility as necessary for building lasting business relationships, especially as scrutiny and technical demands increase.
The ongoing progress in molecular design, pharmaceutical development, agrochemical innovation, and materials science all depend on a strong foundation of reliably produced intermediates. Over the years, we’ve watched our product become a mainstay in large-scale and small-batch synthesis projects. Whether applied in the formulation of advanced crop protection agents, as an intermediate in pharmaceutical research, or as a component in specialty pigment synthesis, this compound reflects the care and expertise of direct chemical manufacturing.
Hands-on experience builds a technical confidence that no certificate or catalog entry can substitute. Customers benefit from our tight process control, robust documentation, and a technical service team prepared to tackle production-scale questions as readily as laboratory troubleshooting. The product’s performance in varied applications continues to drive investment in improved purification steps, better waste handling, and quality innovations.
We see each delivered batch as the result of focused work, reflecting both longstanding technical knowledge and a shared commitment to partnership. With every campaign, both big and small, we prioritize real, measurable quality over generic compliance. The trust we’ve earned from customers comes from doing the work ourselves, learning from every hurdle, and investing in improvements that keep our product at the industry’s leading edge.
