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HS Code |
994155 |
| Cas Number | 2403-88-5 |
| Iupac Name | 1,2,2,6-Tetramethylpiperidin-4-ol |
| Molecular Formula | C9H19NO |
| Molecular Weight | 157.25 g/mol |
| Appearance | White to off-white crystalline solid |
| Melting Point | 62-65 °C |
| Boiling Point | 216-218 °C |
| Solubility In Water | Slightly soluble |
| Density | 0.95 g/cm³ |
| Flash Point | 92 °C |
| Purity | Typically ≥98% |
| Refractive Index | 1.470 |
| Storage Temperature | Store at room temperature |
| Smiles | CC1(CC(CN(C1)C)C)O |
| Synonyms | 4-Hydroxy-2,2,6,6-tetramethylpiperidine |
As an accredited Tetramethylpiperidinol factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Tetramethylpiperidinol is packaged in a 500g amber glass bottle with a secure screw cap and tamper-evident seal, labeled with hazard information. |
| Shipping | Tetramethylpiperidinol is shipped in tightly sealed containers, protected from moisture and light, and kept at a stable temperature. Packaging follows hazardous chemical regulations, with clear labeling and appropriate documentation. Transport is conducted by authorized carriers, ensuring safe handling and compliance with local, national, and international shipping standards for laboratory chemicals. |
| Storage | Tetramethylpiperidinol should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from incompatible substances such as strong oxidizers. Protect it from moisture and direct sunlight. Ensure proper labeling, and keep it away from sources of ignition. Follow all relevant safety regulations and recommendations for chemical storage to prevent contamination and degradation. |
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Purity 99%: Tetramethylpiperidinol with purity 99% is used in UV stabilizer formulation, where it ensures superior photostability in polymeric materials. Low viscosity grade: Tetramethylpiperidinol low viscosity grade is used in coatings manufacturing, where it facilitates efficient dispersion and homogeneous blending. Molecular weight 157.25 g/mol: Tetramethylpiperidinol with molecular weight 157.25 g/mol is used in synthetic resin modification, where it enhances processing and end-product flexibility. Melting point 56°C: Tetramethylpiperidinol with melting point 56°C is used in additive compounding, where it allows for easy incorporation under mild thermal conditions. Stability temperature 120°C: Tetramethylpiperidinol with stability temperature 120°C is used in industrial adhesives, where it maintains chemical integrity during high-temperature curing processes. Particle size <50 μm: Tetramethylpiperidinol with particle size less than 50 μm is used in powder coatings, where it delivers uniform surface coverage and consistent performance. Moisture content <0.2%: Tetramethylpiperidinol with moisture content below 0.2% is used in pharmaceutical intermediates, where it minimizes hydrolytic degradation risks. Solubility in ethanol: Tetramethylpiperidinol solubility in ethanol is used in solvent-based ink production, where it allows for rapid and complete dissolution. |
Competitive Tetramethylpiperidinol prices that fit your budget—flexible terms and customized quotes for every order.
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Tetramethylpiperidinol delivers more than just a catchy chemical name. As a manufacturer handling this compound from start to finish, we see its unique character every day on our production floors and in our laboratories. The molecule typically referenced is 4-Hydroxy-2,2,6,6-tetramethylpiperidine. In straight terms, this chemical builds the backbone for light stabilizer technologies, especially hindered amine light stabilizers (HALS). Much of the world's plastic durability over time owes credit to the stability and electronic qualities of this single building block.
Our product comes with a purity above 99 percent by GC method, and moisture under 0.2 percent. The crystalline solid forms pale white, sometimes carrying a hint of beige—a natural outcome of scaled synthesis and controlled handling. Bulk density and melting point hold steady across batches, ensuring the material fits precisely into high-speed industrial processes. No two manufacturers ever wrap their hands around the same subtle differences, and small shifts in process parameters make big impacts on batch uniformity, color, and handling flow. We monitor everything from raw material origins to the final post-processing under highly scrutinized labs, keeping out contamination and delivering a product our polymer customers trust when the pressure comes on.
Many will ask what sets our Tetramethylpiperidinol apart from powders or liquids floating through the market from different sources. Industry partners count on traceable, consistent material—no hidden organics mixed in, no lingering residual solvents above trace thresholds. Other suppliers might leave traces of tertiary amines or start with broader cuts, but our in-house routes minimize such contamination, putting the chemistry into the right hands with confidence. Because our entire synthesis takes place at facilities owned and operated by our technicians, we keep an eye on every critical control point. This makes surprises unlikely, whether you’re compounding hundreds of kilograms at once or tailoring an additive into a specialty high-end plastic in lower volumes.
Some have pushed for alternate stabilizer routes using different nitrogen structures or imported generations of HALS built on similar skeletons. These variations show up frequently, but end users see the differences in cost control, polymorphic stability, and final product dry time. Tetramethylpiperidinol gives manufacturers a dependable stepping stone for blending HALS families with predictable performance in most thermoplastic and thermoset systems. Engineers working with high-performance polypropylene, polyethylene, and polyvinyl chloride run into less streaking and lower variability in long-term UV resilience compared to some substitutes.
In long runs, minor impurities or moisture can start a snowball effect, showing up as yellowing, gas evolution, or erratic melt flows. Working with Tetramethylpiperidinol direct from source, our partners cut the risk of unplanned downtime and batch waste. Shipping bulk solids in sealed, inert-lined drums and secondary containment, we reduce the oxidative pathways and ensure customers don’t have to hunt for trouble a year down the line. For many technical users, hands-on day-to-day experience outweighs what a textbook or paper describes. So much production hinges on little things: how smoothly a powder feeds, how it withstands the heat of melt blending, or whether any residue forms after storage in extreme humidity.
Compounding plants count on repeatable purity, both to satisfy their reliability testing and to fulfill regulatory compliance for end-market goods. Most regulators around the world hunt for manufacturing records that show exactly what has gone into a given batch of children’s toys or medical plastics. Our plant engineers build documentation that not only tracks the product chain but keeps to strict clean room standards year-round, making evidence-based traceability a daily priority. In recent years, increasing demand from automotive interiors, wire and cable insulation, and agricultural films means stricter controls and tighter supply chain management.
It’s not just about ticking off analytical purity. The physical robustness of Tetramethylpiperidinol means easy integration into industrial workflows. Powdered material, handled by our team, resists caking and compression during shipping, which means automated systems continue running without bridging or feeder blockages. Thanks to careful milling, granulation, and sieving, processing teams don't halt production for lump removal or unexpected particle size mismatches. The steady melting point—usually right around 130 degrees Celsius—fits into existing equipment parameters, preventing delays from re-calibration or adjustment.
Our operator technicians regularly field testing requests or provide small custom lots for demanding R&D programs. That practice goes back decades, with every batch sent for external verification and internal QA before it finds a path onto a truck. Customers working at the front lines of polymer science expect a tightly monitored production chain and energetic response for troubleshooting. On rare occasions, upstream raw materials present challenges: an off-spec feedstock batch or interruption to supply lines. In those times, we push our contingency plans, including parallel sourcing and pre-qualified storage protocols, to eliminate customer risk.
For anyone working in the polymer additives space, Tetramethylpiperidinol means a reliable route into HALS systems and other advanced stabilizers that hold up to long-term sun exposure and weathering. Agricultural film makers tell us stories about materials holding out for months in the field under UV stress, with lower rates of cracking or color fading. PP and PE profiles used for outdoor structures or playground equipment receive critical benefits from this additive, showing lower embrittlement and better surface finish over time.
Automotive interiors face notorious heat, sunlight, and aggressive cleaning chemicals. By including this chemical as a base for stabilizers, carmakers and OEM suppliers achieve not only greater resistance but also better cost control by lowering replacement and warranty claims. In cable jacketing and industrial wire coatings, users report smoother extrusion and less gassing at elevated temperatures, with less discolored product at windup. Lab plastics—especially those for demanding medical and food packaging—profit from its robust analytical purity and consistent rinse-off profiles, with less cross-contamination of sensitive contents.
As new front-line materials in electronics and renewable energy roll out, Tetramethylpiperidinol continues to draw attention for its compatibility in flexible displays, light diffusers, and specialized optical coatings where molecular integrity over time demands tight manufacturing tolerances. Research teams nudge us for input or for feedback about custom blending approaches. We share detailed model-specific analytics on request, helping pinpoint any outlier in process or performance.
Chemical manufacturers know there are other piperidines, morpholines, or sterically hindered amines on the market. Each brings a slightly different reactivity and additional profile of decomposition products when subjected to heat and UV. Tetramethylpiperidinol stands out not just by approvals or spec sheets, but by having a well-documented degradation pathway that users have mapped out and trusted in commercial plastics for years.
Customers with experience in compounding can pick up on subtle changes in volatility or purity just by color, odor, or reactivity in downstream blends. We often compare our own lots side-by-side with batches brought in from resellers or importers. Even brands with close nominal specifications often show broader particle size distribution or higher residue, leading to hopper issues or inconsistent profiles during melt mixing. By managing the entire chain—and choosing only high-purity inputs—our Tetramethylpiperidinol avoids those headaches, reducing the need for filtering and cleanout downtime.
Other stabilizer families sometimes run up against regulatory doubts over long-term leaching or unknown reaction byproducts. Decades of polymer formulators keep coming back to Tetramethylpiperidinol because it holds up in both aggressive aging tests and real environmental conditions, sometimes outpacing emerging alternatives in speed and certainty of qualification. This means lower revalidation costs and consistent throughput for our industrial customers.
Scaling Tetramethylpiperidinol demands more than simple textbook chemistry. Raw material selection, reactor control, and post-recovery all play crucial roles in defining how the final product fits into finished goods. Each batch receives close inspection for not just residual starting materials but for the formation of structurally similar amines or minor alcohols, as these can affect the long-term physical properties of compounded plastics.
We’ve faced years where key raw material shipments ran slow or showed quality shortfalls due to international logistics disruptions. In those times, our vertically integrated plant lines enabled tighter control, even running smaller batch reactors or drawing on pre-qualified reserve stocks. This makes us less vulnerable to trade swings compared to brokers or traders who lack in-house chemistry. Turnaround time for filling truckload orders drops, with immediate feedback available from our own experienced chemists and operators who know the process in and out.
Growing regulatory attention makes documentation matter more every year. Our logistics and QA teams send out new compliance packages to anticipate evolving rules, whether that means chemical inventory registration, REACH dossier updates, or supporting paperwork for direct use in products destined for international markets. Downstream customers rarely have time to chase down product history or purity claims, preferring the reliability and transparency built up over decades between hands-on manufacturers and trusted technical leads.
Quality never happens by accident. Each small upgrade in monitoring and process design comes from day-to-day feedback and collaboration with end users. We listen closely to customers struggling with plastic defects or stability hiccups, sometimes running parallel pilot lines just to find the root cause of an issue that might stem from a single trace compound. Investing in process analytics, microfiltration, or advanced drying protocols pays off when customers report smoother compounding or longer functional life in their final goods.
As forward-thinking industries develop bioplastics or expand sustainable packaging systems, Tetramethylpiperidinol finds new places in stabilizer recipes. Biopolymer blends can be tougher to stabilize due to their inherent variability and reactivity with oxygen or moisture. Our technical teams have spent years mapping out how this molecule holds up under those emerging processing challenges—fielding direct questions from startups and established formulators alike.
Processing teams need chemical inputs that keep control over aging, color, and mechanical properties even in unsheltered outdoor settings or under high thermal loads. By delivering tight specification control, we help materials stand the test of real-world conditions—something manufacturers learn cannot be left to chance. End-users often don’t see the chemistry that shapes their playgrounds, greenhouse films, or car seats, but they notice the difference years down the line when parts last longer and hold their original properties.
Future material scientists look for scalable, versatile, and supply-stable options. Tetramethylpiperidinol consistently ranks as a reliable workhorse due to its molecular integrity, clear regulatory landscape, and proven performance across so many platforms. From colored masterbatches to clear and technical grades, this compound finds a home in formulations that demand both aesthetics and serious function.
Long-term collaborations with processors and compounders don’t happen without trust in the unbroken chain from reaction, through QA, to packaging. As a team of experienced manufacturers, we prioritize clear communication and rapid troubleshooting, understanding that setbacks mean downtime. Taste and odor complaints in packaging or transparency gains in optical parts might trace back to chemistry at the additive level. By keeping samples, documentation, and open feedback loops, we give customers clear evidence and practical support.
Many purchasing departments have their eyes on the bottom line, but technical reliability and direct access to manufacturing data often tip the scales. Our Tetramethylpiperidinol stands as a specific example of substance—each container tagged with batch trace, clean lab background, and logistic verification before it rolls out the door. Customer audits and regulatory checks meet a transparent process, built not just for one-off sales but for ongoing industrial confidence.
In summary, Tetramethylpiperidinol shows its value every day, not just as a chemical compound but as proof of what focused, detail-oriented manufacturing can bring to modern industry. Honest handling, direct support, and continuous technical scrutiny keep it at the front of a chemical landscape always marching forward. If you work with advanced plastics, specialty stabilizers, or high-value additive systems, this material carries a weight of experience and industrial proof that makes a difference in final outcomes.
