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HS Code |
906960 |
| Name | Allyl Phenyl Ether |
| Cas Number | 1746-13-0 |
| Molecular Formula | C9H10O |
| Molecular Weight | 134.18 g/mol |
| Appearance | Colorless to pale yellow liquid |
| Density | 1.015 g/cm3 |
| Boiling Point | 213-215°C |
| Melting Point | -47°C |
| Refractive Index | 1.542 |
| Flash Point | 86°C |
| Purity | Typically ≥98% |
| Solubility In Water | Insoluble |
| Storage Conditions | Store in a cool, dry, well-ventilated place away from sources of ignition |
As an accredited Allyl Phenyl Ether factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
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Purity 99.5%: Allyl Phenyl Ether with purity 99.5% is used in pharmaceutical intermediate synthesis, where it ensures high yield and minimal contamination. Molecular Weight 134.18 g/mol: Allyl Phenyl Ether with molecular weight 134.18 g/mol is used in resin manufacturing, where it provides controlled reactivity for polymerization. Viscosity 0.7 cP: Allyl Phenyl Ether with viscosity 0.7 cP is used in organic coating formulations, where it allows for enhanced flow and even distribution. Boiling Point 215°C: Allyl Phenyl Ether with boiling point 215°C is used in high-temperature polymer synthesis, where it maintains stability and prevents premature evaporation. Stability Temperature 180°C: Allyl Phenyl Ether with stability temperature 180°C is used in specialty elastomer production, where it retains molecular integrity during processing. Refractive Index 1.532: Allyl Phenyl Ether with refractive index 1.532 is used in optical material synthesis, where it achieves desired transparency and light transmission. Water Content <0.05%: Allyl Phenyl Ether with water content less than 0.05% is used in catalyst preparation, where it minimizes hydrolysis and optimizes catalyst performance. Melting Point -50°C: Allyl Phenyl Ether with melting point -50°C is used in low-temperature adhesive manufacturing, where it ensures fluidity and uniformity at sub-zero conditions. Density 1.014 g/cm³: Allyl Phenyl Ether with density 1.014 g/cm³ is used in fine chemical formulations, where it provides precise volumetric dosing and consistency. Flash Point 83°C: Allyl Phenyl Ether with flash point 83°C is used in solvent blends for inks, where it enhances safety by reducing flammability risks. |
| Packing | 500 mL amber glass bottle with secure screw cap; labeled "Allyl Phenyl Ether", chemical formula, hazard symbols, and manufacturer details. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Allyl Phenyl Ether is typically packed in 200 kg drums, loading about 80 drums (16 MT) per container. |
| Shipping | Allyl Phenyl Ether should be shipped in tightly sealed containers, away from heat, sparks, and open flames. It must be handled as a flammable liquid, with proper labeling and in accordance with applicable transport regulations (UN 1993, Class 3). Ensure secondary containment and ventilation, and avoid incompatible substances during transit. |
| Storage | Allyl phenyl ether should be stored in a cool, dry, well-ventilated area away from direct sunlight, heat sources, and incompatible materials such as oxidizing agents and acids. Use tightly sealed containers made of compatible materials. Store away from ignition sources, and ensure proper labeling. Personal protective equipment should be used when handling. Follow local regulations for safe chemical storage. |
| Shelf Life | Allyl Phenyl Ether typically has a shelf life of 12-24 months when stored in a cool, dry, tightly sealed container away from light. |
Competitive Allyl Phenyl Ether prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615380400285 or mail to sales2@liwei-chem.com.
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Tel: +8615380400285
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Bringing Allyl Phenyl Ether to market is not just about delivering a chemical; it's about drawing on a wealth of experience in synthesis, purification, and consistent batch quality. Many of us have worked in this sector for decades, facing challenges that shaped every step from the raw phenol and allyl chloride sourcing through to finished tanker or drum dispatch. Over time, we have learned how stability, composition, and trace impurity control mean as much to downstream chemists as purity itself, and work daily to ensure each lot surpasses both our own and our customers’ expectations.
The model we offer is straightforward: high-purity liquid Allyl Phenyl Ether engineered for demanding environments. The technical team focuses carefully on removing moisture, residual phenol, and chloride-containing byproducts from every run. Our typical product leaves the reactor with a purity far above 99%, with water content often below 500 ppm. GC-FID methods run as standard for every batch, not just for a yearly check, and those records drive in-house improvement as much as compliance.
Color holds, even in storage, because we control both the feedstock and the reaction parameters. We ship this product as a clear, faintly aromatic liquid, stable in the recommended storage conditions. And yes— we always keep an ear out for the rare lot that falls outside specification and do not hesitate to rerun purification or, if necessary, destroy substandard batch material, because reputation and reliability go hand in hand.
Our customer base drives our focus. Over the years, researchers in specialty polymer synthesis, perfumery, fine chemical intermediates, and pharmaceutical development have all relied on Allyl Phenyl Ether to perform as promised. Chemists prize it as a versatile starting material for Claisen rearrangement, and as a building block for active pharmaceuticals, biocides, and flavor agents. It fills a vital role in the toolbox—not just because it introduces a stable allyl group to the molecule, but because it carries its own gentle aromaticity into end products, which can be a subtle advantage in downstream reactions or applications where off-odors must be minimized.
Working closely with labs developing new proprietary molecules, we designed and improved product grades to accommodate reaction routes with minimal by-product interference. More than a few projects see Allyl Phenyl Ether as the only viable intermediate for specific substitutions, since direct alkylation of phenol rarely achieves the selectivity or yields that industry now demands. Across multiple applications, repeatable results outweigh almost everything else, so our role as producer is to ensure consistency is never a guessing game.
After so many years at the plant and in the lab, the discussion about purity has changed. In early years, “good enough” sometimes crept into the conversation when demand spiked or reagents varied, but downstream failures buried that thinking for good. Pharmaceutical and fine chemical companies will confirm: trace contaminants—even parts per million—can trigger reaction inhibition, unexpected polymer branching, or unwanted color. That leads to expensive rework and headaches for everyone, from production chemists to end-users.
We run every batch through spectroscopic and chromatographic analysis to watch for not only known byproducts, but also the rare, unpredictable compounds that can form in minute quantities. The advantage of vertical integration—handling everything from feedstock down to packaging—means we control what leaves our facility. By keeping material streams and production lines dedicated, we reduce cross-contamination risk. Shelf stability is another key point: we use nitrogen blanketing and dry, clean containers to address product stability in storage and shipping. Through this, the customer receives material as close in composition to the day of synthesis as possible.
Every container of Allyl Phenyl Ether begins with careful hands and the wisdom of generations in distillation and product handling. Automated controls govern the reactor, but the skilled eye and nose of a production chemist still matter when the run reaches critical stages. Distillation columns, maintained for peak separation, yield a product that honors its specification because the person on duty knows the difference between “close enough” and “trusted.” Rigorous cleaning and regular line checks reinforce our reputation.
This attention-to-detail sometimes means delaying shipment if a batch doesn’t pass muster. Though that can frustrate, experience has shown the long-term relationship with a customer means more than a short-term sale. The value of this trust shines extra bright in an industry facing never-ending pressure to cut corners and speed up output. Day in, day out, it’s the work at the bench, in the control room, and on the loading dock that delivers not just product, but peace of mind.
Years of head-to-head comparison with other ethers, such as anisole, or with phenol derivatives, consistently highlight Allyl Phenyl Ether’s unique energetic balance and reactivity. The presence of an allyl group unlocks selectivity in certain cross-coupling and rearrangement reactions where methyl or ethyl ethers falter. Anisole, while widespread, lacks the reactivity required for rearrangement pathways and cannot transfer an allyl moiety with the same yield or reliability.
The challenge in developing reliable chemical syntheses comes down to controlling not only reactivity, but also minimizing side products. In contrast with phenoxy compounds containing halogens or bulky alkyl groups, Allyl Phenyl Ether sits at a sweet spot: sufficiently reactive for coupling, but much less prone to form difficult-to-separate byproducts. Its thermal stability allows for higher reaction temperatures without premature decomposition, an edge that plays out directly in throughput for large-scale manufacturing.
No advanced formulation or process development is free from the demands of regulatory and environmental safety. Unlike certain alkyl phenyl ethers which may resist biodegradation or release problematic breakdown products, Allyl Phenyl Ether’s breakdown profile presents fewer environmental headaches. This feature gives research teams and production managers breathing room when planning for scale-up or facility upgrades involving effluent treatment.
With every consignment, we include not only a certificate of analysis but also our own observations from the production log. Direct, open lines between our lab and the customer make issues easier to catch before amplification. When a downstream issue surfaces, feedback loops operate in real time, not just by email but, where required, by phone or site visit. Many of our technical sales people are chemists first, so conversations center not just on price and delivery, but on root-cause analysis and practical solutions.
No product leaves our facility without a traceable pedigree. Batches remain documented through all stages of processing, and records go back years, not just weeks. This has proven essential more than once—unraveling the unexpected, addressing compliance questions, and supporting further innovation.
Years in logistics have taught us the real impact of improper handling: contamination, container failures, and temperature-induced spoilage can erase weeks of good work in production. We use compatible materials to line drums, and enforce strict dryness standards. Staff receive regular training in spill containment, vapor control, and emergency measures—not just on paper, but through drills and on-the-job mentoring.
We recommend, and our own practice bears out, that Allyl Phenyl Ether stores best under an inert blanket at ambient temperature, away from light and sources of ignition. Keeping it dry is crucial, as water can degrade both quality and performance. Documentation travels with every batch, from batch records to shipping logs, ensuring full traceability.
Laboratories and plants reporting best results with our material share one practice: a final visual and olfactory check before introducing it to their synthesis. Old-school? Maybe, but some traditions persist because they work.
The last few years have made clear how fragile global supply lines can become. Long-term manufacturing roots, an established supplier network for raw phenol and allyl chloride, and diligence in logistics shield us from many shocks that upend unprepared operators. Being able to stockpile raw materials without loss, and respond rapidly to new demand, keeps us in the game when less diversified or less prepared competitors run dry.
Our partners, especially those in industries where process reliability runs on a knife-edge, find extra value in a supplier whose chemical and process know-how runs deep into the workforce. We welcome technical audits, collaborative troubleshooting, and shared research, because time spent together in the lab or on the plant floor often reveals not just problems but new product ideas.
Running a chemical plant in years past called mostly for good operators and sound equipment. Now, with market demand for greener processes and greater transparency, we have invested steadily in process intensification and waste minimization. Our facilities use carefully monitored, closed-loop systems to reduce emissions. Waste management practices shift as science advances, and we adopt new protocols for recycling, solvent recovery, and energy-efficient process heat.
The development of Allyl Phenyl Ether reflects a broader industry move toward more sustainable products and technologies. Regulatory pressure applies, but for most teams here, pride in clean chemistry motivates us before enforcement ever does. We continue to experiment with alternative raw materials and greener production auxiliaries—sometimes at added short-term cost, but with an eye on longer-term resilience and respect for the communities around us.
Labs and plants increasingly push the boundaries on what they demand from intermediates like Allyl Phenyl Ether. Whether under the scrutiny of a new pharmaceutical submission or benchmarking a new industrial-scale polymer process, customers rely on straightforward, honest feedback about capabilities and limits. By participating directly in collaborative trials and joint research ventures, we stay out in front of where the market is heading.
Open access to analytical data is standard for us. We welcome blind retesting, third-party audits, and comparative runs against global benchmarks. The real reward comes not from a standard sale, but from seeing Allyl Phenyl Ether provide a breakthrough yield, shortened reaction sequence, or a dramatic reduction in production downtime for a partner.
Making and shipping specialty chemicals confronts us with the unexpected. Our history includes supply disruption from port closures, raw material shortages, and sometimes regulators demanding changes overnight. Each forced a rethinking—rerouting supply, temporarily tweaking batch sizes, or even adding new purification steps at speed.
Veterans here share stories of chemistry that didn’t work as planned, and lost sleep over whether the next shipment would land on time. These setbacks forged a culture that values flexibility and quick learning over rote adherence to “the way it’s always been.” Newer team members learn by asking not only "how do we fix this?" but "how do we prevent it next time?" Every lesson adds resilience to our systems and results in better product for the next customer in line.
Our relationship with the people who use Allyl Phenyl Ether matters as much as the product itself. From the reaction vessels to the loading docks, everyone in the plant knows that the next batch could become a critical active ingredient or unlock a new material for tomorrow’s industry. That responsibility fuels our focus on reliability, open dialogue, and the patient, often unseen craft behind every container shipped.
In the rapidly evolving world of chemical manufacture, true value comes not from product listed on a spreadsheet, but from the trust built over years of problem-solving, partnership, and mutual respect. Allyl Phenyl Ether stands as a testament to what careful, conscientious production makes possible.
