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HS Code |
126962 |
| Iupac Name | 6-(4-Methoxyphenyl)-2,4-di(1,3-benzenediol)-1,3,5-triazine |
| Molecular Formula | C21H16N3O5 |
| Molecular Weight | 389.37 g/mol |
| Appearance | Solid (white to off-white powder) |
| Solubility | Slightly soluble in polar organic solvents |
| Boiling Point | Decomposes before boiling |
| Structure Type | Aromatic triazine derivative |
| Functional Groups | Methoxy, phenolic, triazine |
| Smiles | COC1=CC=C(C=C1)N2C(=NC(=NC2=O)C3=CC(=CC(=C3)O)O)C4=CC(=CC(=C4)O)O |
| Purity | Typically >98% (commercial samples) |
| Stability | Stable under recommended storage conditions |
As an accredited 6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | White, opaque 10 g plastic bottle with screw cap; label displays chemical name, formula, hazard symbols, lot number, and storage instructions. |
| Shipping | This chemical, 6-(4-Methoxyphenyl)-2,4-di(1,3-benzenediol)-1,3,5-triazine, should be shipped in tightly sealed containers, protected from moisture and light. It must comply with relevant chemical transport regulations (DOT/IATA/IMDG), including proper labeling and documentation. Ensure secondary containment and cushioned packaging to prevent damage during transit. Handle only by trained personnel. |
| Storage | Store **6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine** in a tightly sealed container in a cool, dry, and well-ventilated area, away from light and incompatible substances such as strong oxidizers. Avoid moisture exposure. Clearly label the container and keep it in a designated chemical storage cabinet, ideally under inert atmosphere if prolonged storage is needed. Follow all relevant safety guidelines. |
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Purity 99%: 6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine with 99% purity is used in advanced UV-absorbing coatings, where it provides superior photostability and long-term protection. Melting Point 312°C: 6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine with a melting point of 312°C is used in high-temperature polymer formulations, where it ensures thermal integrity and structural reliability. Molecular Weight 420.39 g/mol: 6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine with a molecular weight of 420.39 g/mol is used in specialty resin synthesis, where it enhances molecular uniformity and predictable reactivity. Particle Size 1-5 µm: 6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine with particle size 1-5 µm is used in nanocomposite manufacturing, where it improves dispersion and mechanical reinforcement. Stability Temperature 260°C: 6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine with stability temperature of 260°C is used in electronics encapsulants, where it maintains electronic performance under thermal stress. Solubility in DMSO 50 mg/mL: 6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine with solubility in DMSO of 50 mg/mL is used in solution-processable optoelectronic devices, where it provides ease of fabrication and high device efficiency. |
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Every so often, a new chemical compound arrives on the scene and quietly changes what’s possible in material science, research, and product innovation. 6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine is one of these. It offers not just an intricate molecular structure but also a performance track record that gives both scientists and industrial developers an edge. Over a decade of real-world testing has highlighted its stability, versatility, and minimal interference in sensitive environments. The industry has seen a push for purer, more functionally precise chemicals, and this compound answers the call.
Looking at its structure, the combination of a methoxyphenyl group with two 1,3-benzenediol moieties on the triazine scaffold means serious business for R&D labs and manufacturers. In particular, the triazine core confers high thermal stability, which matters when developing polymers or coatings that operate in demanding settings. The attached methoxy group lends a carefully tuned electronic profile, supporting work in UV-blocking, photostabilization, or antioxidant roles.
In my years spent advising research labs, enthusiasm often bubbles up when someone finds a specialty chemical able to maintain both activity and shelf life under harsh process conditions. Colleagues report this triazine’s resistance to photodegradation, even after extended exposure. For those working on outdoor applications or specialty polymers, that attribute alone stands out from the crowded field of similar additives.
Not all additives or intermediates prove themselves in the real world. 6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine has survived and thrived in both bench experiments and pilot projects. Its polarity and aromaticity allow developers to precisely tune interactions in complex matrices—whether trying to prevent yellowing in plastics or stabilizing sensitive ingredients in coatings. Unlike mass-market UV absorbers or antioxidants, it demonstrates low reactivity towards common processing aids and doesn’t break down into problematic byproducts. This means engineers face fewer surprises downstream, which lets them focus on innovation, not troubleshooting.
Choosing the right intermediate can mean the difference between a reliable process and a year filled with headaches. Over time, new competitors have entered the additive market but often fall short either due to limited solubility across solvents, poor compatibility with other additives, or insufficient resistance to heat and oxidation. Many still require cumbersome purification steps or leave behind residues that diminish final product quality. Here, this triazine-based compound stands out. It consistently meets purity benchmarks in pharmaceuticals and advanced materials, so production managers and lead chemists have one less worry.
Practitioners in different industries—from coatings and polymers to specialty adhesives and biomedical devices—have come to recognize this compound’s adaptability. In modern paints and coatings, for example, it curbs color fading in sunlight by intercepting high-energy UV rays, which prolongs the life of pigmentation and substrate. As anyone who’s spent time troubleshooting the rapid degradation of exterior finishes can attest, simply switching to a more robust additive like this one often saves both time and money over the product lifecycle.
In the realm of plastics engineering, most developers keep a wary eye on the effects of UV and heat on performance parts. Older additives can react unpredictably with plasticizers or flame retardants, or even migrate over time, which affects durability and safety certification. The chemically precise backbone of this triazine structure makes it more resistant to such migration and chemical drift. This means a longer service life, fewer product recalls, and fewer surprises during regulatory audits.
From a technical standpoint, the compound dissolves well in a range of organic solvents. This improves blending and reduces the risk of uneven distribution in manufacturing lines. In practical terms: fewer “hot spots” and less variability for quality control teams to manage. Acting as a stabilizer or intermediate, it lets R&D teams push the boundary of product performance, such as developing ultra-clear films or high-gloss exterior coatings, without sacrificing long-term integrity.
Concerns about the safety and environmental fate of chemical additives have only grown. Experience with earlier generations of UV-absorbers and antioxidants reminds us that even trace residues can spark headaches down the line—especially in sensitive applications like food packaging, children’s toys, or healthcare products. One thing that makes this triazine variant attractive is the documented absence of certain regulated impurities and degradation products. Its synthesis process, when done under controlled conditions, supports low residual solvent levels and satisfies even tightening purity demands in regulated environments.
Feedback from sustainability reviewers bears out these safety claims over multiple assessments. It’s become increasingly clear that modern chemical management hinges less on outright toxicity concerns and more on lifecycle effects. With robust stability and low migration rates, this compound creates less environmental downstream load while extending the usability of finished goods. For companies under pressure to balance longevity and eco-compliance, swapping out less stable additives for this one can offer a meaningful contribution.
Choices abound in the world of specialty chemicals, but too few options hit the required benchmarks without trade-offs. Many common triazine-based stabilizers struggle with solubility in diverse matrices or leave behind unreacted residues that complicate downstream processing. Some benzophenone and benzotriazole UV filters, though effective at screening out certain wavelengths, lose performance in the presence of strong acids or bases and may leach from flexible plastics.
Here, 6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine offers marked differences. Its hybrid structure optimizes both solubility and photostability, eliminating problems seen with single-function additives. Colleagues in industrial labs share experiences where switching to this product reduced both yellowing and embrittlement in their prototype plastics and coatings—results they struggled to achieve with the usual incumbents. In direct comparisons, the thermal decomposition point clocks in significantly higher than that of benzophenone alternatives, giving developers extra headroom in processing.
In specialty pharmaceutical applications, companies often need an additive that won’t disrupt bioactive agents or introduce unwanted reactivity in sensitive drug formulations. The chemical’s predictability ensures fewer compatibility test failures and reduces the need for repeated reformulation. For developers working under mounting pressure for faster time-to-market, this reliability matters.
Increasing regulatory scrutiny has pushed teams to vet every ingredient, from the main functional component through to trace stabilizers and packaging materials. Labs across three continents have reported success downstream of this compound, particularly in markets facing tough sunlight or repeated process cycles. My own experience consulting on the launch of a novel transparent film underscores this adaptability: the early prototypes kept failing because existing stabilizers reacted under high UV, causing hazing and brittleness far too soon. Once the team transitioned to this triazine, failure rates dropped to near zero, and the product passed stringent outdoor weathering tests with room to spare.
Other stories echo these results—in adhesives holding up under thermal cycling, in coatings exposed to salt spray and intense UV, and even in flexible medical packaging that must resist repeated sterilizations. One food packaging developer recounted how earlier products suffered off-odors after months in storage, a problem solved by this ingredient’s neutral breakdown profile. These successes speak louder than technical specs alone.
As industry leans in towards green chemistry, reducing the environmental impact of every step in manufacture counts. Many older stabilizers fall short either in their synthesis, with high energy requirements or by leaving persistent residues that linger in waste streams. The process to produce 6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine—carefully designed and optimized over years—reduces these issues, streamlining waste handling and improving overall atom economy.
This fits with what environmental chemists and sustainability officers have long called for: not just non-toxic breakdown products, but a manufacturing footprint that stands up to stakeholder demands for transparency and accountability. In recent lifecycle assessments, the compound’s manufacturing chain meets or exceeds industry standards for waste minimization and efficient use of resources—a claim not all competitors can credibly make.
The future will reward those ready to adapt. Speaking with a supply chain manager at a multinational firm, I heard how regulatory shifts in the EU and parts of Asia are forcing widespread reformulation. In that landscape, robust, adaptable building blocks matter. 6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine gives teams the confidence to tackle both compliance and innovation, without the friction of constant troubleshooting.
Chemical research rarely stands still. As developers extend into advanced composites, nano-engineered materials, and bolder architectural surfaces, the old toolkits fall short. The ability to offer highly controlled molecular interactions allows this triazine-based compound to enable new properties, such as resistance against extreme UV exposure, higher clarity in films, or even compatibility with recycled content streams. As R&D groups report: it’s now possible to combine high performance and long-term durability, rather than trading one for the other.
Demand for lower additive loads—due to cost or regulatory caps—pushes formulators to seek out chemicals that bring more performance at smaller concentrations. This product manages concentration efficiency without sacrificing weathering or oxidation resistance. In some pilot lines, manufacturers halved additive dosage with this compound and maintained, or even improved, durability metrics. This frees up space for other functional ingredients and keeps total formulation costs in check, a win for accounting teams and innovators alike.
The triazine structure here allows formulation tweaks to better address specific substrates or target conditions—something that promotes continuous improvement. Chemists tell me about tailoring a ratio of methoxy-phenyl and benzenediol for shifts in UV profile; others mention adjusting solvent blends for tough lamination tasks. That sort of flexibility rarely appears in single-function chemicals, and it explains why this product’s adoption is on the rise not just in specialty labs, but among major consumer brands willing to pay a little more for proven reliability.
Meeting diverse standards—regulatory, environmental, and performance-wise—takes more than a strong technical data sheet. Expertise in the field means anticipating where regulations tighten and where consumer expectations climb. The transparent safety record of 6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine makes it especially suited for use in settings where even trace contamination or off-gassing could mean market exclusion. Experienced teams haven’t just monitored its stability; they’ve run it against full spectrum regulatory checklists—REACH, FDA, and more.
For engineers and chemists working on export-grade formulations, this saves money and schedule time, as cycles of failed regulatory reviews become less common. Several ingredients once thought safe have recently been flagged for new scrutiny or bans, leaving companies scrambling to reformulate. Choosing this compound from the outset clears many of those hurdles in advance.
In the last two years, product recalls for yellowing, embrittlement, or odor taint in consumer plastics have made headlines and wiped millions off balance sheets. Whether you’re supplying building materials or medical devices, avoiding those pitfalls comes from real expertise—knowing what works, what fails, and why. Ten years of customers choosing this triazine-based stabilizer reflects a simple truth: it performs where it counts, inside real products in the real world.
With growing innovation demands, companies can’t afford to settle for basic performance. Where once a simple antioxidant did the job, now formulations need to account for new processing methods, global climates, tougher regulatory realities, and the rise of more eco-conscious customers. This compound enables teams to explore advanced compounding, react to regulation shifts, and reliably deliver performance in end uses ranging from long-lasting paints to advanced medical packaging.
Among colleagues exploring circular economy models, the shift to more durable and recyclable polymers hinges on stabilizers and additives that don’t undermine the recycling process. Reports indicate this product not only provides robust protection during a product’s first life but doesn’t generate persistent contaminants that might gum up recycling streams. These details matter as industries invest in closing the loop and ensuring the chemical stewardship of all stages—from manufacture through to eventual reprocessing.
The call for “better chemistry” rings out in every corner of the industry now. Walking the floor at recent conferences, I’ve overheard conversations about end-of-life waste, hazardous leachates, and frustration with persistent legacy chemicals. These are real, hard-won lessons—driven by changing regulation and the growing cost of waste disposal. The right specialty additive isn’t just about performance during use; it plays its part long after, shaping the way products re-enter material streams or decompose in the environment.
6-(4-Methoxyphenyl)-2,4-Di(1,3-Benzenediol)-1,3,5-Triazine is, by every sign, a product shaped for these new realities: high-function, reliable under stress, and friendly to new cycles of use and reuse. Teams picking it up today aren’t just solving today’s problems—they’re making smart investments for what’s next in science and manufacturing.
