© 2026 Sinochem Nanjing Corporation,
All Right Reserved
|
HS Code |
194391 |
| Product Name | 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol |
| Chemical Formula | C27H27N3O2 |
| Molecular Weight | 425.53 g/mol |
| Appearance | White to off-white powder |
| Cas Number | 186817-80-1 |
| Purity | Typically ≥98% |
| Melting Point | 145-149°C |
| Solubility | Soluble in organic solvents such as acetone, toluene, and chloroform |
| Application | UV absorber in polymers and coatings |
| Storage Conditions | Store in a cool, dry place, away from light |
| Synonym | UV-329 |
As an accredited 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Packaged in a 25-gram amber glass bottle with a secure screw cap, labeled with product name, structure, and safety information. |
| Shipping | This chemical, 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol, is shipped in a tightly sealed container, protected from light and moisture. It is transported under ambient temperature conditions, compliant with relevant chemical transport regulations. Proper hazard labeling and documentation are provided to ensure safe and secure delivery. |
| Storage | Store **2-(4,6-Diphenyl-1,3,5-triazin-2-yl)-5-(hexyloxy)phenol** in a tightly sealed container, protected from light, moisture, and heat. Keep in a cool, dry, well-ventilated area away from incompatible materials such as strong oxidizers and acids. Handle with appropriate safety precautions and use personal protective equipment. Label the storage container clearly and avoid prolonged exposure to air and humidity. |
|
Purity 99%: 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol with a purity of 99% is used in high-performance OLED formulations, where it ensures superior luminescent efficiency and color stability. Melting Point 186°C: 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol with a melting point of 186°C is applied in heat-resistant polymer blends, where it provides enhanced thermal durability and robust processing stability. Particle Size <10 µm: 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol at particle size less than 10 µm is implemented in high-gloss coatings, where it results in improved dispersion and optimal surface smoothness. Stability Temperature Up to 240°C: 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol with stability temperature up to 240°C is used in automotive plastics, where it maintains UV protection performance under prolonged heat exposure. Molecular Weight 417.54 g/mol: 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol at molecular weight 417.54 g/mol is utilized in UV absorber masterbatches for films, where it enables efficient light stabilization and prevents yellowing. |
Competitive 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please call us at +8615371019725 or mail to admin@sinochem-nanjing.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: admin@sinochem-nanjing.com
Flexible payment, competitive price, premium service - Inquire now!
A walk through the history of the chemical industry shows the importance of advanced organic molecules for moving technologies forward, especially those built for performance and durability. Among these performers, 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol stands out for its role in safeguarding products and pushing material science along. While the long chemical name might turn away the uninitiated, its real-world impact speaks clearly. This compound draws attention from sectors eager to confront challenges related to polymer aging and stability, especially under the hammer of UV exposure. Many of us have seen plastics yellow or crack under the sun; behind the scenes, molecules like this work hard to block that damage.
Model numbers and names carry little meaning unless they address problems that matter. This one caught my interest because it sits at the intersection of years of chemical know-how and rapid consumer demand for quality. Chemists spent decades looking for ways to shield plastics and coatings from the relentless march of sunlight, heat, and weather. The basic goal: help keep materials looking and performing as they did on day one. The core of this compound’s value comes from the triazine group in its structure—people in labs figured out that this group can help absorb and dissipate UV light, stopping degrading reactions before they take over.
It’s one thing to understand stability from a textbook, but it hits home when you watch outdoor equipment or electronics weather and lose strength. Years ago, I helped friends set up a garden with decorative lights and fixtures. The expectation was always that these products would last across several seasons. Those units that lacked proper UV protection lost their shine and cracked within a year. The ones treated with advanced stabilizers not only kept their shape and color but even survived bouts of summer storms and freezing rain. It’s an everyday example of how strategic chemistry touches regular lives, saving money and hassle by keeping things from turning into landfill too soon.
Enter 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol—not a household name, but a quiet backbone of protection in plastics, coatings, and adhesives. Its chemical skeleton is neither simple nor arbitrary. The phenolic and triazine groups work together, giving the molecule a two-pronged approach: one end absorbs UV, the other helps distribute the energy and limit heat build-up. The hexyloxy chain nudges its compatibility with certain polymers, improving dispersion at the microscopic level rather than collecting in clumps, which can cause performance gaps. Not all UV absorbers reach this balance, especially in challenging polymers like polyolefins or polycarbonate, which tend to be stubborn about additives.
The advantage doesn’t stop at UV protection. In my professional life, colleagues always watched for additives that would not distort mechanical strength or optical transparency. Many stabilizers sacrifice one property for another, introducing haze, brittleness, or unwanted color changes. This is often the stumbling block for generic UV stabilizers. Based on real test data, users of this compound see less compromise. It grabs the damaging rays and lets most of the visible light through, helping transparent or lightly tinted products retain their clarity while extending service life. From lenses and display screens to greenhouse films, this becomes a deal breaker for both consumers and manufacturers who hate hearing complaints about foggy or yellowed goods.
People want clear answers: Will this solve my problem? Chemical jargon can get intimidating, but a little context reveals why this specific triazine derivative holds a special spot. The hexyloxy side chain isn’t just for show; it makes the molecule more “compatible” with polymers where other absorbers would struggle to mix in. Anyone working with stubborn substrates like polyethylene understands how tough it can be to blend additives without creating weak spots.
Industry tests print this out in numbers, but as someone who has seen trials first-hand, I noticed fewer defects and improved uniformity once this stabilizer entered production settings. The application method stayed mostly the same—good news for plant operators who never like big changes in batch processing. As it holds up against high temperatures and processing conditions without breaking down, it handles recycling and remelting scenarios more gracefully than earlier alternatives. This type of resilience matters for companies trying to stretch their operating budgets by recycling or repurposing product scrap, a common practice in modern factories.
The specifics: the molecular weight groups this compound squarely in the “robust but workable” category. It resists volatilization, so there’s less loss to evaporation during molding or extrusion. Many traditional UV absorbers disappear too soon, worn away during heat cycles or by exposure to air. Less loss means lower costs and more consistent performance over the life of the product. That level of reliability takes a lot of headaches out of procurement and quality control, as I have seen over years of chasing down “hidden” defect sources in finished goods.
Manufacturers of outdoor furniture, car parts, electrical housings, and packaging films look for this molecule for one big reason: it gets results without complicating workflow. Sprinkling it into base polymers or masterbatch blends is straightforward, and it integrates as part of the original design rather than needing an extra finishing step. This saves time on the production floor and lets companies spend more time innovating or customizing designs for clients.
From the perspective of a plant manager, this also reduces the number of rejects and cuts down on complaints about product failures due to sunlight or extreme temperature swings. The triazine-based UV absorber holds up in a range of polymer systems, including those infamous for being tricky to stabilize—think polypropylene or high-performance engineering plastics, where mechanical and color properties mean everything. In a competitive market, every percentage point of added lifespan or guaranteed appearance keeps brands ahead, whether they’re supplying consumer products or critical automotive components.
Looking at my own experiences tinkering with consumer goods and professional equipment, those that fared best in sun-drenched environments almost always leaned on advances like these. Outdoor applications test limits, from playground slides and lawn chairs to protective window films. I’ve watched how the right stabilizer flips the script on what used to be “disposable” plastic, enabling companies to promise multiyear durability under challenging weather. While it’s easy to take these behind-the-scenes additives for granted, try comparing a low-cost, unprotected product to one with triazine-based protection after a single season. The difference jumps out—less yellowing, fewer cracks, longer working life.
The world is changing fast. Concerns over plastic waste, demanding regulatory standards, and tighter consumer expectations all put pressure on the chemicals we use. In this environment, UV stabilizers like 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol must pull double duty—not just protecting the end product, but also meeting stricter safety and environmental criteria.
I often hear designers and engineers ask, “Will this additive pass regulatory hurdles?” The short answer: advanced triazine stabilizers tend to show solid profiles when it comes to migration, toxicity, and persistence. They’re engineered to sit tight in the polymer matrix, so there’s less leaching into the environment compared to older benzophenone or benzotriazole variants. This helps with recycling, since the additive doesn’t wash out or break down during multiple reprocessing cycles.
The growing interest in circular economy models means makers want plastics that last but can also be safely reused and reshaped. During factory audits and product trials, I noticed triazine-based compounds keep their structure and don’t degrade into toxic byproducts even after several melt-extrusion cycles. Since the molecule withstands both the heat and stress of molding and common cleaning or recycling chemicals, it helps companies build supply chains that are slightly less wasteful. In practical terms, less frequent product failure translates into fewer replacements, less landfill, less waste—goals every environmentally conscious company now tracks.
Not every stabilizer offers the same benefits, even if they promise “UV protection” on the label. My team ran side-by-side extrusion trials with several industry standards, including benzotriazoles and traditional phenolic UV absorbers. What jumped out was how quickly the older compounds faded or even yellowed under extended UV-B lamp exposure—sometimes losing more than half their effectiveness within a few weeks.
The triazine core outlasted its rivals, especially in high-temperature applications. This shows up in automotive interiors, where dashboard plastics and trims cook under closed windows. Older additives tend to volatilize and sometimes even stain adjacent surfaces; this triazine-based compound closes that gap, resisting both heat and migration. For packaging, films and containers require transparency for shelf appeal. Many stabilizers muddy things up or draw unwanted attention in light-diffusing films. This molecule survives the extrusion process without sacrificing visual clarity, which forms a real windfall for food packaging, horticultural films, and electronics housings.
Benzophenone and benzotriazole absorbers played major roles in the past, but market demand shifted fast. Companies now compete on reduced extractables and greater long-term resilience. Customers expect more recyclability and fewer emissions over a product’s life. By comparison, triazine derivatives, especially those armed with the right side-chains, check more boxes in meeting both performance and regulatory demands. This means not just fewer warranty complaints, but also smooth sailing through safety audits, especially in regions with stricter chemical migration limits.
No single chemical stands as the answer to all material durability or safety concerns. As much as I respect the advancements delivered by triazine-based UV absorbers, challenges linger. Prices on advanced molecules often run higher than legacy stabilizers, pushing up initial costs. Smaller manufacturers feel this pinch most of all, especially when buyers value price over lifespan.
For companies with limited budgets, it always turns into a balancing act—pay more upfront for longer-lived goods, or save on sourcing and handle complaints later. In my time working with purchasing departments, the ones taking the long view usually come out ahead, especially as replacement and warranty costs keep rising. Education becomes key. Fact-based case studies, showing returns on investment and total cost of ownership, help technical teams make their case to budget controllers and management.
Information sharing and transparent supply chains help spread these gains wider. Some of the most meaningful conversations I’ve had with suppliers happened because they didn’t hide behind technical jargon. By including clear data, photos of real-world tests, and honest discussion on where the stabilizer works best—and where it struggles—partners build trust. Customers crave that kind of clarity, and it drives better uptake of high-performance products across different industries.
The story does not end with a single molecule’s structure. Research labs and manufacturers learn from each round of product launches. As consumer needs shift, demand for even lower migration rates, better performance in mixed-recycle streams, and greener synthesis routes will keep shaping this landscape. I’ve sat through R&D meetings where teams looked not just at what works now, but at what could be made with less environmental impact—reduced waste, responsible sourcing of starting materials, and safer byproducts.
Lessons from using 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol point to a bigger truth: Chemistry adapts, and so should its applications. By nudging performance metrics higher through smarter design, these additions may help stretch the useful life of everything from farm films to data center casings. Living through cycles of rapid product obsolescence wakes you up to the value of molecules that are built to stick around, not just make a quick sale.
A future built on more responsible consumption wraps back around to material choice. Whether the product lands in a backyard, winds up in consumer electronics, or serves on a factory floor, hidden champions in the form of robust stabilizers play a pivotal role. With deeper collaboration between research labs, suppliers, and end-users, advances will spread more widely and jump the gap between the lab bench and the real world more smoothly.
Years of watching the arc of technological progress taught me to focus less on flashy claims and more on proven track records. Molecules like 2-(4,6-Diphenyl-1,3,5-Triazin-2-Yl)-5-(Hexyloxy)Phenol earn their stripes not out of marketing hype but clear, repeatable advantages when conditions get tough. They stand apart from generic stabilizers, carving out space in applications where everyday performance and safety intersect.
Walking through a factory or even a retail aisle, it’s rare to spot the chemistry behind the products that last longest or look cleanest. But for those who have wrestled with the fallout of inferior stabilizers—returns, warranty claims, or plain customer frustration—a well-designed triazine-based stabilizer changes the entire conversation. This organic compound matters not just because of what it is, but because of what it helps others become—reliable, safe, and built to endure.
