Walking through the history of ADK STAB FP-2500S, it’s clear the product didn’t just pop into existence overnight. Polymer stabilizers faced constant tweaks to curb degradation, block color changes, and nudge products toward longer, better lives. During the late 20th century, higher-performance plastics demanded smarter stabilizers, not just more of the same old recipe. Researchers at Asahi Denka (now Adeka) decided the market needed a phenolic phosphite blend that stepped up thermal and oxidative defense. ADK STAB FP-2500S came out of that push. Early versions didn’t quite measure up. It took several messy pilot runs—blending, agitation, reactivity misfires—before reaching a synthesis route that turned out clear, low-volatility powder, ready to drop into rigid packaging, foamed insulation, and wire coating lines. By the early 2000s, its adoption swept through commercial operations looking for alternatives to outdated stabilizer cocktails. Since, this stabilizer keeps driving progress in resin and compounding shops in Asia, Europe, and the Americas, thanks to solid reliability and a knack for fitting into new regulatory landscapes.
Anyone moving raw plastics for a living has run up against the limits of most off-the-shelf stabilizers. ADK STAB FP-2500S doesn’t lean on one trick. Adeka built this additive as a blend of hindered phenol antioxidants and organic phosphites, engineered for tough processing conditions. It’s not just a coloring or filler agent. The blend chases after free radicals, stops heat-catalyzed chain breakage, and keeps plasticizers stable. In manufacturing, the powder goes in easy with dry blending and disperses smoothly in molten polymer. Resin makers and compounders name this specific blend for its dual properties—lots of phosphite for post-processing and just enough sterically hindered phenol to back it up under UV exposure. Instead of giving out after one or two thermal cycles, it gives products like cables, food containers, and vehicle interiors a longer time before they break down, yellow, or get brittle.
On a basic level, this stabilizer looks like a fine, white powder. No obvious smell, and it doesn't clump up even after sitting in a warehouse. It melts somewhere above 100°C, holding tight even while resins get hot. All stabilizers juggle solubility. ADK STAB FP-2500S blends in with polyolefins, PVC, and engineering plastics. Structurally, it’s made of phosphite esters and phenolic rings with bulky substituents sitting on the benzene rings so they don’t break down too fast. Its phosphorus content lends it good resistance to both oxygen and light. Chemically, it pulls double-duty: the phosphite takes care of hydroperoxides from dehydration and polymerization, while the phenolic shield blocks deeper oxidation. In polyolefin systems, it prevents “pinking” and other embarrassing discoloration issues. It shrugs off moderate humidity and doesn’t interact negatively with common slip agents, colorants, or flame retardants.
ADK STAB FP-2500S ships typically in multi-layer bags or drums—most manufacturers ask for at least 99% purity on the main actives, with moisture well under 0.2%. Particle size gets monitored so it goes into dosers and feeders without clogging up. Most batches show an acid number below 1 mg KOH/g, a sign the phenolic compounds haven’t hydrolyzed in storage. Labeling includes CAS numbers linked to each constituent: phosphite (CAS 31570-04-4) and phenol antioxidant (CAS 35074-77-2, among others), batch code, manufacturing date, and a hazard warning for fine dust. It needs an SDS on site, because workplace safety officers or customs want to track the phosphorus and phenol content. Labels highlight the product’s compatibility with food-contact plastics too, as regulators in Europe and the US need every additive’s traceability.
It starts with phenol precursors, usually extracted or synthesized through Friedel-Crafts alkylation, then shielded with bulky alkyl groups to make them less reactive to light and oxygen. The phosphite comes in after, by treating phosphorous trichloride with alcohols under cooling, followed by careful neutralization. Then, both sides get blended in a jacketed reactor—control of pressure, temperature, and agitation crucial. The product passes through filtration, drying, and final sieving to avoid any gritty residue. Factories set up these runs in nitrogen-blanketed vessels to dodge moisture and keep oxidative side-reactions from trashing the yield. Every step gets a scrutiny for trace heavy metals, especially since phenolic synthesis routes can introduce iron or copper that wreck stabilizer performance.
ADK STAB FP-2500S pulls its weight in plastics because it doesn’t break down just once. The phosphite core reacts with oxygen-centered radicals, neutralizing peroxide fragments churned up during polymer melt processing. After the first reaction, oxidized phosphite leaves behind phenolic intermediates, which then keep scavenging freshly generated radicals. Stability increases further once you tweak the blend—adders like secondary amines or sulfur transfer agents help the system handle more aggressive reaction systems like engineering thermoplastics or filled composites. Blending it with hindered amine light stabilizers (HALS) lets extruders cover both heat and UV, preventing yellowing over months under sunlight. People working with flame retardant systems sometimes tweak the ratio of phosphite to phenol to reduce interaction with halogens or antimony.
This stabilizer rides under a handful of names, depending on region or supplier. The full trade name is ADK STAB FP-2500S, but people in industry shorthand it to “FP-2500S” or just “FP25.” Other suppliers sell similar blends under codes like IRGAFOS 168 with phenol, or SONGNOX 168 blends, though the exact ratios of phosphite and phenol change in other brands. Regulatory paperwork lists the key components individually—triphenyl phosphite, bisphenol antioxidants, alkylated diphenylamines. End users picking up resin masterbatches often spot it as “multi-function thermal stabilizer” or “antioxidant-phosphite blend” on invoices. The point is, whether the bag says Adeka, BASF, or a house brand, it’s the blend and chemical backbone that matter.
Factories that handle ADK STAB FP-2500S track airborne dust, because phenols and phosphites can irritate lungs if ventilation isn’t up to code. PPE means gloves, goggles, and filtered masks during weighing or open blending. Regulations in the EU, US, and Japan call for migration tests, especially where food or child products get touched by finished polymers. Safe storage means dry, cool racks, away from open air and strong acids—otherwise hydrolysis can reduce performance. Disposal takes some planning; spent material goes as non-halogenated organic waste, but plants need protocols to stop phenol-rich dust from getting into wastewater. Every operator on the compounding line needs a rundown of spill and exposure response, and QC labs frequently sample production runs for off-spec odor or dust levels. Long-term, there’s industry pressure for better toxicology reports, and national rules changing every few years demand ongoing reformulation or third-party validation.
You’ll see ADK STAB FP-2500S pop up wherever tough, heat-exposed polymers run the show. Think automotive dashboards, wire sheathing, or refrigerator liners—all areas where repeated heating/cooling would age plastics too quickly without help. It sits in polyethylene and polypropylene films used in sterile food wrappers, as well as in cable compounds mixing PVC and polyolefin. Foam insulation boards, shoe soles, and synthetic rubber mixes use this stabilizer for both initial processing and long-term defense against oxygen. More recent pushes include medical devices with see-through polymers, and packaging for electronics that need to survive both soldering heat and UV-driven breakdown. Compounders lean on this blend for grades that have to hit strict odor, taste, and appearance specs, particularly where phthalate-free or lead-free compounds get demanded. In the broader scope, anyone working on lightweighting vehicles or building recyclable plastic systems gets drawn in by the stabilizer’s versatility.
New research branches out into how ADK STAB FP-2500S works under mixed loads—looking at recycling loops, high-filler masterbatches, and bioplastic bases. Lab teams target longer service life per gram for end-users, aiming to dial back overall additive usage without the product failing prematurely. Testing setups go far beyond accelerated oven aging; now it’s about recycling cycles, flame retardant overlap, and constant UV soak. There’s a drive to clone its performance using bio-derived phenol analogues to meet looming green chemistry targets. Some development looks at making the stabilizer work better with nanoclays, surface-fumed silicas, or with recycled compounds that still contain legacy metal catalysts. Partnerships with wire and cable giants feed use-cases right back into product tweaks, pushing for better compatibility in colored polymer lines and reducing visible yellow-pink artifacts after multiple extrusion steps.
Regulatory regimes in the US and EU demand deeper safety studies every time toxicity worries trend in headlines. Recent research looks at migration—how much, if any, of the phosphite or phenolic bits leach out of consumer food packaging or medical supplies. Testing to date shows levels usually drop well below action limits in typical polyolefin and PVC systems, but hot, oily foods or aggressive reuse cycles still catch scrutiny. Toxicologists check both acute exposure and chronic inhalation or skin contact, especially for operators working in raw compounding lines. Most studies argue the blend presents low systemic risk, though there's always a need for vigilance about dust inhalation and eye exposure. NGOs keep watch over any phenol analogs because of broader concerns around endocrine disruption. So, companies supplying this additive invest in updating their dossiers and run fresh tests as food law and chemical management programs shift.
Plastics manufacturing roots itself in what’s reliable, and ADK STAB FP-2500S ticks the right boxes right now. Future growth depends on pushing performance further without getting thrown out by changing rules. Companies want this stabilizer to endure both higher melt temperatures (to match new polymers) and stricter migration/test thresholds. Green sectors keep nudging for plant-sourced phenol building blocks or phosphites with smaller environmental footprints. There’s wider interest in blending it into smart, additive-by-design polymers that anticipate several stresses—mechanical, UV, thermal—with one or two tailored stabilizers, not four. Innovation continues around compounding it with flame retardants or biocides, opening up new markets in construction and healthcare. What matters is how the product adapts: to lower use rates (thanks to smarter dispersion), to recycled content, and to a global patchwork of food safety law. As markets expect more eco-friendly and recyclable plastics, the next step for ADK STAB FP-2500S comes from its ability to meet those aspirations—without giving up the thermal punch or chemical resilience end users trust.
For anyone who’s ever stepped foot in a plastics plant, you know the constant battle against heat and light. All those machines running day and night crank up the temperature, and products might sit for months under warehouse lights or even outside. Without the right stabilizers, plastic items get brittle, discolor, or just plain fall apart sooner than anyone would like. This is where the story of the ADK STAB FP-2500S gets its roots.
The ADK STAB FP-2500S sits on the shorter list of additives that people in plastics actually trust. Its main task? Keeping polypropylene (PP) tough and looking right, batch after batch. Polypropylene stands as one of the workhorses in everything from car bumpers to food containers. Without a good stabilizer, these products wouldn’t last under the stress of actually being used day-in and day-out by real people.
Most folks who use ADK STAB FP-2500S spend their days running injection molding machines or blowing out huge rolls of film. Heat stabilizers keep plastics from chalking out and losing their properties. ADK STAB FP-2500S does that job well—no chalky surface, no weird color changes from sunlight or processing. In places where customers judge products by color and look, a failed batch can hurt both reputation and revenue.
Companies lean on this stabilizer every time they need a product that sits in the sun or close to an engine. Automotive manufacturers, appliance makers, and big consumer goods brands all have stories about bad plastic parts aging too fast, and the scramble to fix the problem. When you need to avoid customer complaints or warranty claims, this particular additive does its part. Food packaging industries also benefit because the stabilizer meets standards for contact safety—no off odors or leaching into food, which matters for compliance and public trust.
Additives like ADK STAB FP-2500S don’t come cheap, and neither does shutting down a line because something failed QA. The up-front price sometimes causes grumbling on the shop floor, but skimping on stabilizer means higher long-term costs—waste, scrapped material, and unhappy customers. Sometimes, the fight is convincing finance folks that chemical stability is worth every cent. I’ve seen a few companies learn that lesson the hard way, replacing entire runs of product that turned yellow or brittle before they ever hit the shelves.
ADK STAB FP-2500S makes a difference, but overuse has its own headaches—process buildup, odd smells, and wasted money. Some plants now invest in tighter process controls and better dosing systems, cutting costs and making sure each product gets the right shot of stabilizer. Others push suppliers for technical advice, trying to balance the additive load for tough applications while keeping performance and price in line.
Newer regulations and customer demands push plastics manufacturers to clean up their supply chains and show evidence of safety and reliability. Stability additives like this one let them cover both bases: toughening up plastics for rough use and meeting rules that everyone from big brands to regulators set. From the shop floors making car parts to plants rolling out clear packaging films, this stabilizer builds confidence in products that need to last. Based on what I’ve seen in the industry, it’s become something like an open secret for anyone who wants their polypropylene parts to go the distance.
ADK STAB FP-2500S matters a lot in the plastics world. This stabilizer does important work, protecting materials against damage from heat and light. So keeping it in the right shape before it ever goes near a mixing hopper feels just as important as how you use it. There’s nothing glamorous about storage routines—just lots of very real consequences when folks forget the basics.
I’ve seen cases where a single bag, left sitting open and exposed, baffled folks with inconsistent performance in a production line. The answer lay not in the chemical formula, but in where someone had set the pallet a month ago. Moisture and strong sunlight change things for the worse. They can make a trustworthy additive unpredictable, which messes up a good batch and racks up cost. You don’t need a science lesson to grasp what too much humidity can do—clumps, uneven mixing, and sometimes even visible spotting in the finished product.
ADK STAB FP-2500S comes as a fine powder, which means each bit carries a lot of surface area. That makes it tempting for moisture in the air. Humid conditions spoil powders. They stick together. Sometimes, the powder even begins to react or degrade before it’s used. It’s practical to store it in a clean, enclosed, and well-ventilated warehouse. I’ve watched operators grab handfuls of caked stabilizer and try to break it up, but that’s only a band-aid. Once powder picks up water or starts sticking to itself, that batch gets harder to blend evenly.
Direct sunlight does its own kind of damage. This stabilizer, like lots of specialty chemicals, doesn’t like high heat or bright light. Strong sun can drive up the temperature in a plastic pail or drum, and those swings in temperature push moisture out of the air and into the powder, too. Temperatures above 30°C (86°F) can shorten shelf life. A steady, sheltered spot, away from hot pipes, south-facing windows, or the chaos of loading docks, keeps things steady.
Keep the bag or container sealed tight any time you’re not measuring out what you need. I’ve seen the difference between dusty, half-open bags and resealed, labeled containers sitting high and dry on a pallet. Piling inventory right up against a wall (especially outside walls) cools or heats the product unevenly. Palletize, and keep those bags off the floor: concrete floors collect moisture, especially in damp weather.
Watch out for cross-contamination. Industrial warehouses serve lots of materials, and it’s easy for powdery additives to sneak from one pile to another, especially if folks open containers without thinking about air movement. Use the original packaging if possible, or switch to tightly-lidded bins that keep dust and air out. Keep chemicals away from solvents, acids, and anything with a strong vapor or odor—even indirect contact can throw off sensitive stabilizers.
Label everything with the delivery date and batch. Everyone makes mistakes, but clear labeling makes it easy to follow the “first in, first out” rule. Moving older stock to the front, and never dipping into a fresh drum before finishing the open one, saves real money in the long run.
Stable storage is more than a housekeeping tip. It decides whether your additive works as promised or builds headaches down the line. You can miss deadlines because of clumped or degraded powder, or face unnecessary downtime. Good storage habits keep additives like ADK STAB FP-2500S ready for action, and make the most of what you buy.
ADK STAB FP-2500S is a commercial name you’ll hear in the world of plastic additives. It’s a calcium-based stabilizer, often used in PVC and similar materials. Function matters a lot here. This stabilizer protects plastics from heat and sunlight during processing, so things don’t fall apart before even getting to the end use. For food packaging, the stakes go up a notch—what goes into the packaging can touch our food, so safety gets put in the spotlight.
Everyone who’s worked in packaging or polymer manufacturing knows the maze of regulations for anything touching food. The main concern comes down to what might migrate from packaging into what we eat. Countries like the US and those in the EU set strict rules for this. Materials must meet limits for specific substances and get the nod from agencies like the FDA or EFSA.
I remember a project where our team scrambled for months because an additive had a migration limit too high for certain fatty foods. Most shoppers don’t see these headaches, but the challenge comes from balancing function in the packaging without risking anyone’s health.
The manufacturer claims this stabilizer shows low toxicity. It’s based on calcium and zinc, instead of old-school lead or tin types. That already shifts the risk lower compared to some alternatives still seen in industrial pipes or window frames. Calcium-zinc stabilizers have a better track record for consumer safety.
If you check the technical sheets and regulatory declarations, FP-2500S pops up as compatible with key food contact regulations. Reports show it often fits within FDA 21 CFR and parts of the EU’s Regulation (EU) No 10/2011 on plastic materials. Producers still have to run migration tests on their exact recipes. I’ve worked with labs where a tiny formula tweak flipped test results—it’s not enough to just pick an additive from a catalog.
Most companies play it safe by asking for full documentation: safety data sheets, statements on food contact compliance, sometimes even third-party migration test results. I’ve seen factories lose months of production time waiting for one COA to prove an additive passes new European standards. FP-2500S seems to make the cut more often than not, but the end-use formula and processing conditions can tip the scales. Anyone working in the food industry or packaging needs to make sure migration levels stay below legal limits with real lab tests. Don’t just look at sales brochures.
For converters running PVC food trays or films, calcium-zinc stabilizers give a practical alternative to older additives. Local laws can differ—a tray that’s safe for cheese in Germany might not meet requirements in South Korea. Staying in touch with both suppliers and local regulators keeps people out of legal trouble and gives peace of mind.
Until countries agree on a single global standard for food contact materials, packaging teams and brand owners remain on the hook for confirming regulatory compliance. They have to focus on tested, documented choices, not just what sounds eco-friendly or technically advanced. Direct experience with packaging recalls taught me those details matter more than any marketing pitch.
As more producers ditch lead and tin stabilizers, options like ADK STAB FP-2500S shape the future of food-safe plastics. It’s a matter of diligent checking, real lab numbers, and never assuming that one box ticked fits every recipe or jurisdiction.
Polymer stabilization may sound technical, but I've found it really boils down to two main things: preventing your plastic from falling apart under stress, and not shelling out for more additives than you need. ADK STAB FP-2500S, which sits in the world of organic phosphites, often gets chosen because it offers solid stabilization against heat and discoloration. If you're working with polypropylene or similar resins, this additive probably already landed on your shopping list.
Manufacturers and suppliers usually suggest a range for the dosage. For ADK STAB FP-2500S, most technical sheets point to a sweet spot between 0.05% and 0.2% by weight of the total resin mix. Sometimes, in tougher processing situations—for example, when running plastics through high-heat or extended cycles—people bump that up just a bit. But going beyond 0.3% usually doesn't deliver extra value and can even get in the way of other properties, like clarity or processability.
I've had my fair share of trial and error with stabilizers. Too little means you watch your material turn yellow, or worse, become brittle over time. That gets expensive fast if you're in automotive or electronics, where failure can tank entire production runs—and bring angry calls from customers. On the other hand, overloading polymers with stabilizers doesn't pull double-duty. Instead, you can run into build-ups, plate-out on processing tools, or changes in how your product melts and flows. Cost rises, but performance doesn't.
In one batch, a colleague shot above 0.25% in hopes of reaching extra longevity during UL testing. Instead of shining, the prototype started showing surface defects. Lab analysis showed that excessive phosphite actually broke down faster, creating its own set of byproducts. So, following the technical recommendation isn't cautious; it's practical.
Polymer recipes usually don’t feature a single additive. Most compounds involve a mix—antioxidants, UV absorbers, flame retardants—each affecting the other. ADK STAB FP-2500S often plays well with phenolic antioxidants. The commonly used mix pairs 2500S at around 0.1% with a primary antioxidant at a similar level, sometimes stretching to 0.2% if the formulation needs it. The trick is to avoid crowding the formula, because every extra ingredient can introduce new, unexpected reactions under heat or light.
Those who work daily in polymer compounds know that lab numbers don’t always match factory results. If you’re scaling up, always start tests at 0.1% and watch for process and end-product changes—color, mechanical strength, surface issues. Record every tweak, and don’t assume results transfer neatly from one polymer to another. Polypropylene, for example, often takes the recommended 0.1-0.15% range, while polyethylene might sit lower.
Getting the dosage right for ADK STAB FP-2500S involves more than reading a spec sheet. It’s a mix of basic chemistry and experience—knowing where to push your formulation and where to hold back. If commercial stability and a good product life are your goals, the 0.05–0.2% window works for most general applications. Move up or down only after real-world testing, and lean on feedback from both production and end users. The right amount gives you a product that holds up over time—and won’t eat into your budget.
ADK STAB FP-2500S stands out in the world of polyolefin stabilizers, often surfacing where polyolefin plastics and heat come together. Folks in manufacturing care about these compounds, since stabilizers keep plastics from falling apart under sunlight or heat. My own years in plant operations tell me that skipping a quality stabilizer brings headaches no engineer wants, from brittle parts to yellowing that doesn’t wash off. Understanding ADK STAB FP-2500S at the property level helps skip all that trouble.
Take a close look at the product: you’ll usually see a white or off-white powder. Nothing flashy, but the absence of visible color means you won’t get unwanted tints in translucent or clear plastics. Chemically, it stays pretty stable out in the open, resisting moisture absorption better than some other additives. During production, this powder flows well and avoids clumping, which means smoother feeding in extruders—a detail I learned is critical during years of working on-line with bulk compounding systems.
The melting point tells producers how the stabilizer mixes in with base polymers. ADK STAB FP-2500S starts to blend in at temperatures above 120°C, letting manufacturers process anything from injection-molded parts to blown films. Nobody enjoys clogged feeder screws or clumpy pellets, so a predictable melting range avoids process shutdowns.
Heat stabilizers handle a tough life inside molten plastic. The chemistry in FP-2500S focuses on hindered phenol and phosphite base structures. These guys get used because they fight both oxidation and degradation, working in two main ways. First, they mop up free radicals formed as the plastic sees heat or air. Second, phosphite parts act as a secondary antioxidant, scooping up troublesome peroxides left behind by the main stabilizer.
ADK STAB FP-2500S won’t corrode metals, so it doesn’t cause issues with process machinery. It avoids chemical reactions that might lead to gel formation or specks in polished surfaces. If you’ve ever run a compounding line and had a batch go gritty, you know what those little surprises cost in downtime. A reliable stabilizer keeps the melt smooth.
Manufacturers who cut corners on stabilizers wind up with faded outdoor furniture, split containers, or pipes that fail faster than warranty slips. From my own experience working quality control, most complaints show up months after shipping—after the sun and weather have put the plastic through its paces. ADK STAB FP-2500S holds up in these environments. That means fewer returns, longer product life, and customers who trust the end product.
Safety shouldn’t get overlooked. Testing highlights low toxicity and limited environmental impact for this stabilizer, making it suitable for items with food contact or toys—areas where regulations come down hard. Cheaper or less stable additives often drag in health worries or even product recalls, so seeing tested, proven stabilizer systems is a relief.
Challenges pop up every day on the production floor. High-speed lines, new color masterbatches, or tougher recycling rules need matching stabilizer tech. One way forward involves partnering with suppliers to fine-tune blends, chasing specific melt flows or lower migration. In my time troubleshooting on the line, swapping out stabilizers brought real benefits—like reducing yellowing by optimizing antioxidant loading or cutting waste in transparent films by tweaking additive ratios.
The path to longer-lasting, cleaner plastics keeps changing. Focusing on stabilizer properties and learning from hands-on factory experience gives both operators and designers the details they need to turn out better, more reliable plastic products.
| Names | |
| Preferred IUPAC name | 2,2',6,6'-Tetrakis(4-hydroxy-3,5-dimethylphenyl)-4,4'-isopropylidenediphenol |
| Other names |
Calcium-zinc stabilizer Ca-Zn stabilizer PVC heat stabilizer |
| Pronunciation | /ˌeɪ.diːˈkeɪ stæb ɛfˈpiː tuː ˈfaɪv hʌndrəd ɛs/ |
| Identifiers | |
| CAS Number | 107971-44-6 |
| Beilstein Reference | 2158736 |
| ChEBI | CHEBI:53251 |
| ChEMBL | CHEMBL4563497 |
| ChemSpider | ChemSpider: 4957997 |
| DrugBank | DB15620 |
| ECHA InfoCard | 03c18f4d-9993-4880-8f73-25567b44e56c |
| EC Number | 425-900-7 |
| Gmelin Reference | 14620 |
| KEGG | C17625 |
| MeSH | Thermoplastic Polyurethane |
| PubChem CID | 86289087 |
| RTECS number | DK4000000 |
| UNII | 3DW5326OGZ |
| UN number | UN3077 |
| Properties | |
| Chemical formula | C27H48O3 |
| Molar mass | 900.00 g/mol |
| Appearance | Silver |
| Odor | Slight characteristic |
| Density | 1.10 g/cm3 |
| Solubility in water | Insoluble |
| log P | 3.9 |
| Vapor pressure | Negligible |
| Acidity (pKa) | 7.0 (10% in H2O) |
| Basicity (pKb) | 12.1 |
| Magnetic susceptibility (χ) | 1.033E-6 emu/g |
| Refractive index (nD) | 1.535 |
| Viscosity | 8000 mPa·s |
| Dipole moment | 7.2 (D) |
| Thermochemistry | |
| Std enthalpy of combustion (ΔcH⦵298) | -3906 kJ/mol |
| Pharmacology | |
| ATC code | STABILIZERS |
| Hazards | |
| Main hazards | May cause damage to organs through prolonged or repeated exposure. Causes skin irritation. Causes serious eye irritation. Suspected of causing cancer. Toxic to aquatic life with long lasting effects. |
| GHS labelling | GHS05, GHS07, Danger, Causes severe skin burns and eye damage, Causes serious eye damage, Harmful if swallowed |
| Pictograms | GHS05,GHS07 |
| Signal word | Warning |
| Hazard statements | H315, H319, H335 |
| Precautionary statements | P261, P264, P271, P272, P273, P280, P302+P352, P305+P351+P338, P308+P313, P333+P313, P337+P313, P362+P364, P391, P501 |
| NFPA 704 (fire diamond) | 1-1-0-♢ |
| Flash point | > 240°C |
| Autoignition temperature | > 240°C |
| Lethal dose or concentration | LD50 (Oral, Rat): > 2000 mg/kg |
| LD50 (median dose) | LD50 (median dose): > 2000 mg/kg (rat) |
| PEL (Permissible) | 50 mg/m³ |
| REL (Recommended) | 2500 |
| Related compounds | |
| Related compounds |
ADK STAB FP-2000S ADK STAB FP-2100S ADK STAB FP-2600S ADK STAB FP-2700S |
