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HS Code |
736035 |
| Iupac Name | N,N-Bis[3-(3,5-di-tert-butyl-4-hydroxyphenyl)propanoyl]hydrazine |
| Cas Number | 32687-78-8 |
| Common Names | Antioxidant 1024, Irganox 1024 |
| Molecular Formula | C34H52N2O4 |
| Molar Mass | 552.78 g/mol |
| Appearance | White to off-white powder |
| Melting Point | 221-228 °C |
| Solubility In Water | Insoluble |
| Solubility In Organic Solvents | Soluble in acetone, chloroform, and benzene |
| Primary Use | Antioxidant additive for polymers |
| Density | 1.1 g/cm³ (approximate) |
| Functional Groups | Hydrazine, phenol, ketone, tert-butyl |
As an accredited N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 500g of N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine supplied in a sealed amber glass bottle with tamper-evident cap. |
| Shipping | The chemical **N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine** should be shipped in tightly sealed containers, protected from light, moisture, and excessive heat. Use appropriate packaging to prevent contamination and spills, and adhere to relevant regulations for transporting chemical substances. Handle with standard laboratory safety precautions during shipping and storage. |
| Storage | N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine should be stored in a tightly sealed container, protected from light and moisture, in a cool, dry, and well-ventilated area. Keep away from strong acids, bases, and oxidizers. Recommended storage temperature is below 25°C. Proper labeling and segregation from incompatible substances are essential to ensure safety and maintain chemical stability. |
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Purity 99%: N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine with purity 99% is used in polymer stabilization processes, where it ensures prolonged oxidative degradation resistance. Melting point 180°C: N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine at melting point 180°C is used in high-temperature plastics manufacturing, where it maintains antioxidant efficiency during processing. Particle size <10 μm: N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine with particle size <10 μm is used in masterbatch formulation, where it allows for uniform dispersion and enhanced protective performance. Stability temperature 220°C: N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine with stability temperature 220°C is used in thermoplastic processing, where it provides consistent antioxidant activity under heat stress. Volatile content <0.2%: N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine with volatile content <0.2% is used in food-contact polymer applications, where it prevents contamination and enhances material safety. Viscosity grade low: N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine with low viscosity grade is used in liquid stabilizer solutions, where it enables easy mixing and rapid antioxidant effect. Molecular weight 638 g/mol: N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine of molecular weight 638 g/mol is used in specialty polyurethane coatings, where it provides excellent long-term stability against UV-induced aging. Ash content <0.05%: N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine with ash content <0.05% is used in fiber production, where it minimizes residue formation and ensures fiber clarity. |
Competitive N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine prices that fit your budget—flexible terms and customized quotes for every order.
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N,N-Bis[β-(3,5-di-tert-butyl-4-hydroxyphenyl)propionyl]hydrazine, or more simply, Hydrazine Antioxidant 3114, stands out in the world of chemical additives. Anyone who’s ever worked with plastics, rubbers, or synthetic fibers knows the struggle against heat, light, and oxygen. Looking back on my early days in a plastics lab, products tended to yellow, crack, or even fall apart faster than expected. After years spent searching for ways to improve stability, this molecule repeatedly proved its reputation for resilience.
The backbone of Hydrazine Antioxidant 3114 brings together two bulky tert-butyl groups and a long hydrazine-linked structure. This design doesn’t just sound technical—there’s real science at play here. Those tert-butyl groups stop free radicals in their tracks, while the hydrazine segment adds extra protection. Without this kind of robust shielding, heat and light start to break down polymer chains, so mechanical strength, color, and usefulness fade away. Based on published studies, the compound’s unique structure allows it to persist longer during high-temperature processing or outdoor use, compared to older Arylamine or phenolic systems.
One doesn’t need to work in research and development to witness the wear and tear that everyday plastics endure. Items like electrical insulation, automotive parts, piping, and even sports gear face relentless pressure from sunlight, hot working environments, or repeated bending and stretching. With each exposure, weak additives let the material degrade. A strong antioxidant not only delays those processes—it helps manufacturers lower warranty costs and maintain customer trust. Polymer engineers, trying to hit lifespan targets for products outdoors or in engine compartments, have turned to Hydrazine Antioxidant 3114 for exactly that reason.
Older phenolic antioxidants came with trade-offs: volatile byproducts, poor compatibility with engineering plastics, or limited activity in blends. In the hands-on world, this often meant yellowing, odor, or brittleness where consistency mattered. By contrast, Hydrazine Antioxidant 3114 interacts less with acids, bases, or peroxides, creating a larger safety margin for thermoplastic processing or high-temperature curing of coatings. Independent test labs report that, at equal loadings, this antioxidant remains active for longer periods, especially when tackling polymers prone to aggressive oxidation like polyolefins or polyesters.
That’s not hypothetical. In an in-house trial with polypropylene, I saw pieces maintain impact resistance noticeably better after weeks of UV exposure, compared to parts stabilized with entry-level antioxidants. The cost per kilogram was slightly higher, but the reduction in returns and field failures more than justified the investment.
This antioxidant delivers on several crucial specifications that matter for plant managers and quality control supervisors. The melting point, around 156-162°C, means it survives most compounding and extrusion processes without decomposing. It has low volatility, so there’s minimal loss during reprocessing or remelting. The compound’s solubility in common solvents makes it easy to work with in both batch and continuous manufacturing, whether dry blending or liquid dosing is the preferred approach.
Most notable, though, is the compatibility with a wide range of thermoplastics, elastomers, and fiber-forming resins. Whether blended with polyethylene, nylon, EVA, or blended elastomers, the antioxidant gets evenly distributed throughout the matrix. Unlike some older stabilizers, it doesn’t bloom out or leave unsightly residues on finished goods. This matters in consumer-facing applications like food packaging and children’s toys, where visual appeal and safety take top priority.
Health and safety topics often get lost in technical talks, but they’re critical to any conversation about additives. Users want to know what kinds of exposure risks come with a chemical and whether it leaves traces in finished parts. Hydrazine Antioxidant 3114, based on several global risk assessments available in open literature, ranks among the most stable and low-migration options in the phenolic antioxidant class. It’s non-corrosive and doesn't easily volatilize under standard processing, so air quality remains manageable. While it’s always essential to follow personal protective equipment guidelines and handle all chemicals with respect, people working on shop floors or near compounding lines don’t have to worry about excessive fumes or off-gassing from this compound.
Further, its low extractability means that end products, from medical devices to electronics, retain their intended function without risk of contamination. Companies already moving towards REACH and RoHS compliance favor Hydrazine Antioxidant 3114 because it simplifies regulatory paperwork and product stewardship.
Plenty of polymers rely on antioxidants like hindered phenols, phosphites, or thioesters. Many of these serve well for certain needs, yet Hydrazine Antioxidant 3114 demonstrates a longer useful life in harsh conditions. Phosphite stabilizers boost initial heat stability but can exhaust themselves facing strong oxidizers, forcing manufacturers to add higher dosages or reprocess rejected stock. Thioesters, often chosen to back up phenolic systems, suffer from higher cost and sensitivity to acids. In a side-by-side comparison on high-impact polystyrene using a standard yellowing test, Hydrazine Antioxidant 3114 preserved color far longer than phosphite-only or thioester approaches. In fact, finished goods held their appearance and mechanical strength through repeated cycles in accelerated aging chambers.
Practical experience shows that adding Hydrazine Antioxidant 3114 doesn't require changes to process flow or costly upgrades to blending lines. It integrates into masterbatches, liquid dispersions, or direct compounding systems, so manufacturers don’t need new feeders or extensive staff retraining. For small and medium-sized enterprises, such simplicity carries real-world value, saving time and trimming overhead costs.
Global plastics production faces pressure from tightening environmental laws and rising end-user expectations. As the world raises standards on recyclability, food safety, and emissions, the additives that go into those products must measure up. Hydrazine Antioxidant 3114 offers one step forward, supporting reuse and recycling with its strong retention of stabilizing properties even after repeated melting and forming. With so much focus on closed-loop supply chains, materials that resist aging or degrade less during recycling help firms make the most of every barrel of polymer.
No molecule provides a magic fix for every challenge, though. Companies running ultra-high-temperature processes, such as high-speed injection molding or fiber spinning, sometimes have to pair Hydrazine Antioxidant 3114 with secondary stabilizers to block color loss or acid formation. Yet, compared to the rotating cast of older options, this compound consistently cuts down early degradation and scrap rates. Over years of consulting with extrusion shops, I’ve watched teams reduce downtime and machine fouling, simply by relying on this more robust antioxidant in their blends.
Today’s consumers want more than just a low price: they expect gear that lasts, packaging that survives shipping and storage, and no unpleasant surprises from contact with water, heat, or sunlight. Brands aiming for stronger reputations and lower warranty costs keep pushing suppliers to tighten up their additive recipes. Hydrazine Antioxidant 3114 lines up with industry moves towards “cleaner” plastics by resisting migration, cutting volatile emissions, and standing firm against extremes of heat and light. From my own time reviewing customer complaints and analyzing product returns, discoloration and fragility dominate the list of failure modes linked to inadequate stabilization. Working with formulations built around this antioxidant, I’ve seen defect rates tumble, service life stretch out, and calls for field replacements drop off.
There’s also a clear trend towards higher recycled content and bio-based resins. Questions often surface about whether traditional antioxidants will play nicely with the ever-rich list of modifiers, colorants, and process aids in next-generation materials. In trials with recycled polyethylene and PET, Hydrazine Antioxidant 3114 enables those reclaimed resins to be blended back into new streams, retaining much of the original properties. For designers and environmental managers tackling real-world upcycling challenges, this kind of additive offers not just technical stability, but also reassurance when reporting sustainability gains.
Polymers serve billions worldwide, from clean water pipes to protective packaging for medicine and food. As manufacturing goes global, any additive must meet a tangled web of standards, from FDA approvals in North America to EN71 compatibility in Europe. Hydrazine Antioxidant 3114 holds up under such scrutiny. Knowing a compound works across major regulatory environments gives decision-makers more confidence to certify products for cross-border sales.
More companies evaluate their supply chains based on life cycle analysis, identifying where waste or environmental impact sneaks in. The thermal and oxidative stability of Hydrazine Antioxidant 3114 allows for repeated heating and forming cycles, reducing waste from off-cuts, rework, or scrapped lots. Less product leaves the factory damaged or prematurely aged, trimming both environmental footprint and production cost. Working with teams championing eco-labels or cradle-to-cradle certifications, I’ve seen this antioxidant become a go-to solution to bridge strict compliance with market-driven pressures for greener materials.
Manufacturers juggling quality, cost, and regulatory compliance often walk a tightrope. Cheaper options on paper don’t tell the full story—persistent issues like discoloration, odor, or polymer breakdown mean more rework and unhappy customers. Hydrazine Antioxidant 3114 comes at a modest price premium, but experience shows the payback comes in performance claims that hold up during customer use, fewer shipments returned for failures, and less time spent firefighting on the production floor. Real data from field testing shows fewer yellowed dishwasher racks, unwarped auto parts, or cloudy food trays, leading supply chain managers to select this option based on true total cost of ownership.
One cannot overstate the peace of mind that comes from using a high-performing antioxidant. Through multiple product launches and design upgrades across consumer and industrial markets, reliance on this additive becomes as much about protecting company reputation as it is about hitting yearly production quotas. In those critical first months after launching a new part or package, customer complaints often stem from overlooked stabilization issues. A robust additive profile helps insulate brands from those first hits, giving research and support teams room to focus on improvements instead of damage control.
Manufacturers keep pushing the limits on processing speed, temperature, and complexity. Gone are the days of forgiving melt cycles or simple single-line compounding. Alongside more aggressive production goals come new forms of mechanical stress, higher shearing rates, and broader compatibility demands. Hydrazine Antioxidant 3114 steps up under these pressures, retaining activity even as cycle times shrink and polymer blends grow more sophisticated.
From personal experience evaluating line trials, I’ve seen first-hand how older stabilizers faded fast under these new operating environments. Batches would yellow or shed strength before shipping, forcing last-minute formulation tweaks and costly quality escapes. The current generation of antioxidants, Hydrazine Antioxidant 3114 among them, doesn’t just “fit in”—it fuels the move toward higher-performance, lower-waste plastics, which lie at the core of the industry’s future.
A side-by-side look at alternatives shows clear differences. Hydrazine Antioxidant 3114 fares better under heat aging, meaning products stay whiter and tougher even after extended outdoor exposure or repeated dishwasher cycles. Its low volatility means fewer risks for process lines and safer shop floor operation. Unlike many phenolic antioxidants, this molecule’s large, wrapped-up structure keeps it inside the polymer, not migrating to the surface or leaching into stored goods. For industries like food packaging, where stability cannot mean trade-offs in safety, this property stands out.
Watching new startups and legacy brands alike tweak their additive blends, I’ve noticed that Hydrazine Antioxidant 3114’s balance of low odor, high performance, and broad regulatory clearance makes it a strong pick. It works in both high-clarity film and tough, structural parts—without forcing a choice between protection and performance. Customers aiming for long shelf-life, brighter colors, or less brittle failure count this product as a linchpin in dependable formulations.
Looking to the future, people across the polymer supply chain expect better; less waste, fewer toxins, and performance claims hold up for longer. From where I stand, Hydrazine Antioxidant 3114 signals one way forward. Its durability, safety profile, and versatility line up with market trends: lighter-weight cars, safer child products, greener construction materials. As teams look to do more with fewer additives, and push towards both cleaner and longer-lasting formulations, Hydrazine Antioxidant 3114 fits naturally into those plans.
In my years tracking product launches, customer satisfaction scores, and audit results, the common thread ties back to stability—both for the product and for the bottom line. This antioxidant doesn’t simply prevent early failures; it helps complete the picture for clients trying to credibly claim improved durability and sustainability. While not a cure-all for every technical requirement, it serves as a solid foundation for modern, demanding manufacturing environments.
The road to cleaner, tougher, and globally compliant plastics is paved with innovation and real-world learning. From my earliest hands-on time in polymer blending bays to current conversations with ESG auditors, Hydrazine Antioxidant 3114 remains a product engineers and managers mention by name when performance dictates the outcome. It embodies a key step along the path to less wasteful, higher-value, and more responsible material development.
For those charged with picking the right chemical tools for the job, this antioxidant stands among a new breed: delivering not just on technical benchmarks but lending credibility to broader corporate claims around safety, efficiency, and global reach. Companies with an eye on both today’s performance and tomorrow’s compliance trends keep it at the center of their material portfolios, allowing them to meet shifting consumer, regulatory, and durability demands with more confidence and less risk.
