|
HS Code |
591479 |
| Iupac Name | 1-(2,4,6-Trichlorophenyl)-3-[3-(2,4-di-tert-pentylphenoxy-acetamido)benzamido]-5-pyrazolone |
| Molecular Formula | C34H36Cl3N3O4 |
| Molar Mass | 656.03 g/mol |
| Appearance | Yellow to orange solid |
| Solubility In Water | Very low |
| Melting Point | Approximately 180-185°C |
| Cas Number | 25607-30-3 |
| Common Use | Analytical reagent (chromogenic agent for metal ions) |
| Boiling Point | Decomposes before boiling |
| Storage Conditions | Store in a cool, dry place away from light and moisture |
| Stability | Stable under recommended storage conditions |
| Hazard Statements | May cause skin and eye irritation |
| Synonyms | Trichloro(pentylphenoxyacetamido)benzamido pyrazolone |
| Structure Type | Aromatic heterocycle with substituted phenyl and pyrazolone rings |
As an accredited 1-(2,4,6-Trichlorophenyl)-3-[3-(2,4-di-t-pentylphenoxy-acetamido)benzamido]-5-Pyrazolone factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging is a sealed amber glass bottle containing 10 grams of 1-(2,4,6-Trichlorophenyl)-3-[3-(2,4-di-t-pentylphenoxy-acetamido)benzamido]-5-Pyrazolone, labeled with safety and handling instructions. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): 12 metric tons, packed in 25 kg fiber drums, lined with PE bags for chemical safety and protection. |
| Shipping | The chemical `1-(2,4,6-Trichlorophenyl)-3-[3-(2,4-di-t-pentylphenoxy-acetamido)benzamido]-5-Pyrazolone` should be shipped in sealed, properly labeled containers, protected from light and moisture, and under cool, dry conditions. Comply with all applicable regulations for hazardous materials, including the use of appropriate packaging and documentation. Handle with gloves and personal protective equipment during transport. |
| Storage | **Storage Description:** Store 1-(2,4,6-Trichlorophenyl)-3-[3-(2,4-di-t-pentylphenoxy-acetamido)benzamido]-5-pyrazolone in a tightly closed container, in a cool, dry, and well-ventilated area. Keep away from direct sunlight, moisture, and sources of ignition. Store separately from incompatible substances such as strong oxidizing agents. Ensure proper labeling and secondary containment to prevent leaks or spills. |
| Shelf Life | Shelf life: Typically stable for 2–3 years when stored in a cool, dry place, away from light and moisture. |
Competitive 1-(2,4,6-Trichlorophenyl)-3-[3-(2,4-di-t-pentylphenoxy-acetamido)benzamido]-5-Pyrazolone 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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Every day in our plant, we handle the complex steps that move 1-(2,4,6-Trichlorophenyl)-3-[3-(2,4-di-t-pentylphenoxy-acetamido)benzamido]-5-Pyrazolone from starting reagents to a tightly controlled final product. Our own synthesis processes leave no room for shortcuts; we maintain a vigilant eye on every variable. From environmental controls to our choice of solvents and purification steps, we focus on keeping impurities well below industry-accepted thresholds. Consistency does not come from luck. Batch records, in-process checks, and robust final product testing form the backbone of reliable manufacturing. This delivers uniform, high-purity product, batch after batch. We see the difference in downstream results and our customers’ feedback speaks to the performance of our compound.
This compound, often recognized in technical circles for selective analytical applications, takes shape through a demanding process. The core structure of the pyrazolone framework, combined with both the trichlorophenyl and the bulky di-t-pentylphenoxy-acetamido benzamido side chains, confers a unique combination of lipophilicity and electron-withdrawing capacity. Our chemists have top-down control over side-product formation and unwanted isomerization. Through continual review of literature and dialogue with top academic groups, we have adopted—and in some areas, improved—various synthesis steps to raise both yield and selectivity. We don’t develop chemistry for catalogues; this product occupies a central place in specialty applications, where performance trumps cost per kilogram.
Most users seek this specialized molecule to exploit its strong ligand properties, especially in separation science or trace metal analysis. Its architecture enables selective coordination with certain metals and polar organic species, making it valuable as a chelating agent in both research and industrial settings. During manufacturing, we pay particular attention to eliminating reaction byproducts that might confound metal binding or interfere with spectral analyses. The t-pentyl groups offer not only enhanced solubility in organic solvents but also resist oxidative degradation, a common pitfall for less robust analogs.
We measure the melting point, purity by HPLC and NMR, and screen for elemental composition at multiple checkpoints. This depth of analysis reflects our experience: slight synthetic deviations show up as shifts in baseline measurements, which, in turn, negatively affect client performance. In one project, our researchers correlated just a half-percent increase in an unreacted acid moiety with greatly reduced selectivity in a customer’s chromatographic system. Process improvement keeps our output within one-tenth percent impurity, giving researchers predictability and process engineers what they need to scale.
Every end-user approaches our compound with a distinct set of application hurdles. Analytical labs demand absolute purity because trace contaminants compromise separation methods and mass spectrometry results. In industrial metal extraction scenarios, operators want high yield without sacrificing extraction selectivity. Both rely on the absence of moisture and air-sensitive impurities. Our answer is airtight packaging, desiccant controls, and small lot verification.
Once in the field, some customers wish to blend our product directly into complex matrices, often at very low concentrations. Fine particle size and precise solubility profile make dissolution efficient. We learned from early client feedback that crystal habit had an impact on dissolution rates and recovery; we now control seed formation and cooling rates in crystallization, which means users see near-complete recovery and minimal undissolved residue.
Analytical chemists often need to adapt our compound to specialized protocols, such as coupling reactions or further derivatization. The absence of catalytic trace metals—verified by ICP-MS—ensures minimal side reactions. Feedback from advanced chromatography groups shaped our drying methods and anti-static handling so the material flows freely and measures consistently, whether handled in milligram or multi-kilo quantities.
Many producers offer similarly structured compounds or broader pyrazolone derivatives, but not all address the compound’s idiosyncrasies with the same rigor. Shortcuts in starting material quality, incomplete chlorination, or uncontrolled substitution routinely produce end products with hidden instability or inconsistent color characteristics. Our own batches exhibit reliably sharp melting points and color, verified by colorimetric analysis, reflecting absence of low-level polymerization and oxidative byproducts.
We go well beyond the industry norm by optimizing for storage over extended periods. Some available alternatives show visible degradation or lose analytical performance after only months; our in-house stability studies confirm that product, stored per our guidelines, remains analytically viable for well over a year with only negligible changes in key metrics. This ensures our compound supports both short-term research runs and extended pilot plant testing without costly repeat ordering or waste from expired stock.
Our own conversations with environmental chemists, for example, have revealed that certain pyrazolone analogs degrade into environmentally persistent byproducts. Through deliberate substitution of the bulky di-t-pentyl side chains, we offer a compound more resistant to environmental breakdown pathways, reducing concerns about persistent residues in aquatic and terrestrial systems.
Based on order patterns and the direct conversations we hold with users, the most common applications fall in coordination chemistry, trace metal chelation, and as an intermediate in high-end pigment or specialty dye synthesis. In rare cases, we have seen creative teams utilize the compound in niche organic synthesis as a selectivity agent, often integrating our feedback about solvent compatibility and reactivity.
The details matter. In regulatory submissions or standardized laboratory protocols, we ensure the documentation includes not only CoA information, but detailed analytical profiles so downstream users don’t need to re-do baseline characterization at their location. Over time, we have documented dozens of case studies where process chemists experienced far higher yields or tighter control over selectivity simply because they began with a cleaner, better-documented input.
For metal extraction operations adopting newer leaching processes, this compound provides a high-affinity alternative to legacy ligands that show poorer environmental or occupational safety profiles. We regularly collaborate with users in scaling reactions from milligrams to multiple kilograms without compromising on isolation methods or compound integrity. Direct client reports confirm our product’s robust handling characteristics mean less waste, fewer false positives, and lower rework rates.
Over years of scale-up, we refined our control strategies across all stages. Early on, we observed that a single variable, such as exposure to light during intermediate isolation, produced subtle shifts in color and end-use efficiency. We now work under controlled lighting and use specialized filters through sensitive steps. Maintainability forms another pillar of quality; we monitor key reactor exposures and minimize downtime, since oxygen ingress during shutdowns can introduce unpredictable impurities.
On occasion, we receive requests for product with tailored particle size or alternative solvent-wetted forms. Our facility, through a continuous improvement process, addresses these in collaboration with process development teams. We check product response to common process solvents, recognizing the importance of avoiding solubility mismatches that can derail project timelines. Responsive feedback cycles between our plant and users led to the adoption of newly designed drying apparatus, further minimizing surface-bound solvents and halogenated residues.
Regulatory expectations evolve. As global standards press for more environmentally conscious chemistry, we invested in resource-efficient purification streams and solvent recovery. Waste streams are monitored and pre-treated to reduce overall environmental burden. Product leaving our facility is fully tracked and supported by supply chain transparency, so no surprises arise during haulage and warehousing.
Consistency makes for trust in research and pilot-scale evaluation. Our routine includes trend analysis of product properties—not just as a perfunctory check, but as a means of tracking long-term process drift. Through the years, we have replaced legacy instrumentation, upgraded to higher resolution NMR and mass spectroscopy, and moved toward digitized batch records that enable rapid tracing in the event of customer inquiries. We find this attention to traceability saves both sides headaches if a special investigation arises.
Technical support does not stop at shipment. Our scientists run real-time batch tracking and field incoming queries around optimal use, compatibility with non-traditional solvents, or fine-tuning of extraction protocols. The best results come from close involvement and iterative exchange of information, and we encourage users to share their experimental feedback. Case-by-case technical advice often lets customers shave weeks from development timelines.
As manufacturers closely tied to both regulatory affairs and practical end-use, we know that the world’s standards around specialty chemicals only move in one direction—upward. Environmental scrutiny contends with performance requirements. Increased awareness about bioaccumulation and toxicity influences not only how our product performs, but how it is handled and disposed. Our in-house toxicologists screen each production run for residuals outside standard monographs, recording outcomes to help downstream users justify regulatory submissions or internal safety reviews.
The trend toward greener chemistry affects both our input chemicals and our handling methods. For example, we moved to high-purity, pre-dried reagents to cut back on unnecessary solvent washes, both for operator safety and product clarity. Bulk solids are now charged under inert atmosphere, shaving downtime and slashing off-gas waste. This demonstrates not just an abstract commitment to environmental responsibility, but delivers measurable savings and performance gains.
Long-term business in the specialty chemical world flows from transparency and results. Buyers repeatedly come back because a process has proven itself over time, not because of marketing gloss. Each kilogram leaving our plant bears the imprint of hard-earned experience and technical knowing—the sort built through seeing both the successes and setbacks on the factory floor. Problems or unexpected findings receive attention from senior process chemists, not sales proxies or anonymous emails. Our doors stay open for technical teams who value the real-world input from people who work daily with these reactions.
Our facility survives and grows due to technical bench strength and a willingness to share hard numbers. We rarely see specifications drift, and when confronted with an application problem, openly share root cause analysis and corrective actions. This cycle of trusted manufacturing deepens with each successful project, returning value to both sides. The complexity of 1-(2,4,6-Trichlorophenyl)-3-[3-(2,4-di-t-pentylphenoxy-acetamido)benzamido]-5-Pyrazolone’s structure deserves respect, and our history with this molecule reflects a lived commitment, not just a claim on a technical data sheet.
Over the years, our best product improvements have arisen from honest conversations with those working at the bench. Early on, users highlighted issues like trace off-coloration or slow dissolution that, at first glance, seemed minor. Several rounds of controlled experiments revealed links to unnoticed process side reactions. These insights translated into tighter controls, which now form the baseline of our batch release documentation.
Analytical partners sometimes push us to explain the origin of minute peaks in HPLC chromatograms. Rather than evade these concerns, our chemists dig in and run targeted impurity profiling, documenting the process and providing annotated spectra. Collaboration around these details not only satisfies customer audits but sharpens our own scientific edge. Rarely do new issues arise without rapid response; onsite staff training reflects the lessons learned from hands-on engagement, ensuring each team member contributes to the broader effort.
Scaling specialty molecules while holding the line on quality requires foundations laid in smaller runs. Each process transfer from kilo lab to pilot plant receives deep scrutiny. Challenges—like ensuring uniform temperature control in bulk reactors or replicating lab-scale agitation patterns—demand not only engineering fixes but also involvement from those who’ve handled these operations start to finish. We invest in operator training, document key learnings, and adapt, so each scaling step retains the chemical’s full integrity and tight specification.
Some customers request customization: adjusted flow properties, pre-mixed blends, or integration with other chemistries. Engaging directly with these projects, we adopt an engineer’s view: minimize uncontrolled variables, map risks, and favor reproducibility. Openly sharing both data and lessons forms the backbone of long-term mutually beneficial relationships. The ongoing dialogue leads to process improvements that become the new plant standard, benefiting the entire user base.
Manufacturing demands attention to the unseen as much as the visible. Control on a micro level—be it in the fine details of each synthetic step or the storage environment for the final product—drives true product superiority in demanding end-use scenarios. Knowing how your chemistry behaves, through years of in-plant expertise and close analytical scrutiny, becomes the hidden force behind every successful application.
Our knowledge grows with every cycle, every analytic, and every challenge set forth by our partners. In specialty chemicals, this hands-on credibility proves as valuable as synthesis skill or analytical throughput. We extend that ethos to every lot produced, supporting users through both routine and complex demands alike.
