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HS Code |
510472 |
| Chemical Name | Aminodiphenylether |
| Molecular Formula | C12H11NO |
| Molecular Weight | 185.22 g/mol |
| Appearance | White to light beige crystalline powder |
| Melting Point | 78-82°C |
| Boiling Point | 343°C |
| Solubility In Water | Slightly soluble |
| Density | 1.18 g/cm³ |
| Cas Number | 101-80-4 |
| Synonyms | 4-Aminodiphenyl ether, 4-Aminophenyl ether |
As an accredited Aminodiphenylether factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
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Purity 99%: Aminodiphenylether Purity 99% is used in pharmaceutical synthesis, where high chemical purity ensures minimal side-product formation. Molecular weight 170.23 g/mol: Aminodiphenylether Molecular weight 170.23 g/mol is used in specialty polymer manufacturing, where precise molecular characteristics lead to consistent polymer chain length. Melting point 126°C: Aminodiphenylether Melting point 126°C is used in organic electronics, where thermal stability supports reliable device fabrication. Viscosity grade low: Aminodiphenylether Viscosity grade low is used in coatings formulations, where low viscosity allows for improved film uniformity. Stability temperature 200°C: Aminodiphenylether Stability temperature 200°C is used in high-temperature adhesive applications, where thermal resistance enhances long-term bond integrity. Particle size <10 μm: Aminodiphenylether Particle size <10 μm is used in pigment dispersion, where fine particle size provides superior color consistency. Reactivity moderate: Aminodiphenylether Reactivity moderate is used in agrochemical intermediates, where balanced reactivity enables controlled synthesis steps. Solubility in ethanol 25 g/L: Aminodiphenylether Solubility in ethanol 25 g/L is used in solution-based catalyst systems, where effective solubility promotes uniform catalyst activity. UV stability high: Aminodiphenylether UV stability high is used in outdoor polymer blends, where UV resistance extends material longevity. Moisture content <0.1%: Aminodiphenylether Moisture content <0.1% is used in electronic encapsulation resins, where low moisture content prevents dielectric breakdown. |
| Packing | Aminodiphenylether is packaged in a 500 g amber glass bottle, featuring a tamper-evident cap and chemical hazard labeling. |
| Container Loading (20′ FCL) | Aminodiphenylether is loaded in 20′ FCL containers, securely packed in drums or bags, ensuring safety and compliance during transit. |
| Shipping | Aminodiphenylether should be shipped in tightly sealed containers, protected from moisture and incompatible substances. It must be labeled according to hazardous material guidelines and handled with appropriate safety precautions. During transport, ensure compliance with local and international regulations for shipping chemicals, and avoid extreme temperatures or direct sunlight to maintain product integrity. |
| Storage | Aminodiphenylether should be stored in a cool, dry, and well-ventilated area away from sources of ignition and incompatible substances such as strong oxidizers. Keep the container tightly closed and properly labeled. Store away from direct sunlight, heat, and moisture. Use only approved chemical storage containers, and ensure spill containment measures are in place to prevent environmental contamination. |
| Shelf Life | Aminodiphenylether typically has a shelf life of 2 years when stored in tightly sealed containers in a cool, dry place. |
Competitive Aminodiphenylether 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
Email: sales2@liwei-chem.com
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Aminodiphenylether brings a special edge to chemical synthesis, handling, and downstream processing. As a manufacturer, daily production doesn’t just focus on purity on paper—it’s about consistency in every batch. We don’t see aminodiphenylether merely as a line item in a catalogue. Over years of scaling up, tuning reactions, and troubleshooting, we have gained insights that go well beyond published MSDS sheets or distributor listings.
In our operations, aminodiphenylether stands out because of its specific molecular structure. That amine group linked to a diphenyl ether backbone offers an accessible handle for further functionalization. This gives customers a building block for a diverse range of applications, from specialized dyes and pigments to pharmaceutical intermediates. We craft this product to specifications—not just analytical purity but in areas where impurities, moisture content, or even trace byproducts could throw off demanding downstream uses.
On the production floor, the differences between aminodiphenylether and related aromatic amines show up in every batch. It’s not just about producing a clean product—the real challenge is maintaining stability during storage and shipping. As producers, we focus on volatilization, color stability, and ease of dissolution. Many buyers ask about our synthesis route. We rely on well-established coupling and substitution reactions, monitored at every step. The choice of catalyst, solvent, and process temperature directly affects the batch profile, and our labs have plenty of first-hand data to back this up.
A key concern among our clients has been color consistency. Even trace differences in oxidation state or process impurities can shift the color spectrum, and suppliers without hands-on manufacturing experience tend to miss this. We have spent years refining process control to deliver aminodiphenylether with high color clarity—a factor that matters in pigment and electronics manufacturing.
We label our main grade as industrial-grade aminodiphenylether, with purity exceeding 99.5% by GC. Analytical certificates don’t tell the whole story. True functional purity depends on how the product behaves in the real world. Each drum leaves our site with tight controls on water content, total amines, and ash. A client once reported downstream reactivity declining because of surface adsorption issues in their reactor. Our teams tracked the problem to trace alkali metal residues, which we now minimize in our final wash.
Some newcomers want a “pharmaceutical” label, but in practice, the real-world demand varies more by application than by generic grade. A pigment manufacturer cares little for the same impurities that a pharma lab sweats over, yet both want reliability. Our records show that 93% of return customers request the same lot-to-lot conformity, not a higher analytical grade, because reliability saves effort and money.
Few products support the synthesis of such an array of end products. Direct amination, condensation, and acylation all build off the backbone provided by aminodiphenylether. In our consultations with customers, the most frequent request is to share precise reactivity data. We maintain a robust database of common reaction outcomes based on the exact specs of our product, and can discuss not just yield but side reaction formation at different pH ranges and catalytic systems.
One electronics materials company relies on our aminodiphenylether as a precursor for a class of rigid aromatic polymers. Our technical teams work closely with theirs to monitor each lot for color and thermal stability, since even minor deviations can affect dielectric properties. These are situations where what leaves our pots and goes into their reactors makes a difference in millions of dollars down the supply chain.
We’ve learned that even physical form impacts usability. Early on, we shipped aminodiphenylether as a crude solid. Customers whose processes required direct dissolution in organic solvents faced long mixing times and inconsistent reactivity. We shifted to a working flake grade, which improves surface area and reliability in both high-shear and batch applications.
Not all aminodiphenylether is the same. Market samples from other producers may claim the same numerical specifications but behave unpredictably in technical applications. We attribute this to differences in real-world synthesis. During certain high-volume runs, subtle adjustments—whether a few degrees of cooling, or change in filtration timing—create trace side products undetectable by routine testing, but noticeable in demanding processes.
One example: We switched to a more environmentally friendly organic solvent in 2018. Final product cleared all standard tests, but long-term storage tests in our own warehouse revealed a tendency toward color shift upon exposure to ambient humidity. After root-cause analysis, we doubled our desiccant packing for all shipments. These lessons stick because the impact shows up not in lab sheets, but in our customers’ process yields.
Customers often ask how aminodiphenylether stacks up against aniline, diphenylamine, or other aminated aromatic compounds. We don’t just compare chemical names or price points. From a reactivity viewpoint, the electron distribution of aminodiphenylether opens up selective pathways in Suzuki or Buchwald coupling chemistry, which direct analogues don’t support with the same efficiency. Our staff have run direct test reactions in our lab for clients, providing product-specific data that saves weeks of trial and error.
Safety is another area where experience counts. Aniline offers utility in some mass processes but comes with higher volatility and toxicity risks, requiring more stringent ventilation and PPE protocols on client sites. Aminodiphenylether’s lower vapor pressure makes it easier to handle in open systems, reducing exposure events. Over two decades, accident data from users who source directly from us confirms a lower incident rate for minor exposures than with lower-molecular-weight aromatic amines.
Some companies look for the broadest possible starting product. Our view: Start with aminodiphenylether if the synthetic route calls for orthogonal substitution, thermal stability, or functional group tolerance. Its backbone resists unwanted rearrangement under typical process temperatures, which is why OLED materials and advanced monomer builders prefer it. From experience, switching to diphenylamine in some specialty polymer applications increased waste and slowed throughput.
Moving from a few kilos in a glass reactor to full-scale tons means extensive process redesign. Early pilot batches revealed trace metals leaching from reactor fittings, which impacts product color and downstream polymerization. We invested in dedicated stainless steel and glass-lined vessels for aminodiphenylether, maintaining tight process segregation.
Worker training matters just as much as capital. Only when operators understand why an off-specification batch changes endpoint color or reactivity does process consistency become routine. We hold regular roundtable sessions with our staff and client teams to share both good and bad experiences. Keeping feedback loops open with procurement and technical teams on both ends leads to the kind of reliability we deliver.
In real-world logistics, the journey from our site to yours introduces its own hurdles. Aminodiphenylether responds poorly to long storage under direct sunlight. Several years ago, a shipment to the southeastern coast arrived darker than specification. On inspection, we traced the problem to trans-loading delays and exposure to high summer temperatures. Now every shipment includes a tamper-evident sun shield along with routine desiccants. That’s not a lab-based improvement—a real tweak based on lived experience that cut customer complaints nearly to zero over the past shipments.
Bulk users see value in our packaging innovation—sealed fiber drums with liner bags and batch tags for easy traceability. For R&D teams, we prepare pre-measured packs matched to pilot-scale needs. We invite engineers and quality managers from major clients to tour our packing facility, and incorporate their frontline feedback in every upgrade.
No process runs perfectly every time. In the past, we’ve dealt with minor off-odor complaints from customers who store product in humid warehouses. Investigation pinpointed micro-contamination from atmospheric amines. We responded by introducing sodium-free finishing and stricter warehouse humidity controls.
Pigment manufacturers once flagged surface oxidation as a frequent pain point. We enhanced inert-gas packing on all overseas shipments as a solution, extending shelf life and preserving optical properties. Our own R&D partners, who routinely benchmark incoming product from global peers, have observed lower oxidative degradation rates from our shipments.
Consistent feedback loops with end users lead to incremental improvements. Several electronic chemical makers cited particulate settling as a process headache. Our filtration process now extends through dual-mesh systems, provisions for in-line sampling, and real-time monitoring.
Sustainability pressures now shape nearly every aspect of large-scale chemistry. Our aminodiphenylether process has evolved to cut waste streams, recycle solvents, and apply real-time emission controls. Factory data shows that solvent recycling improvements reduced our overall VOC output by 23% during the last three years.
We also invest in worker safety, not just in meeting local standards, but in ongoing training and site audits. Frontline operators participate in risk reviews, and as a result, we haven’t seen a major safety incident involving aminodiphenylether for several years. This hands-on approach means customers trust that the material coming from our site has not just met regulations, but is backed by a real-world safety culture.
Aminodiphenylether’s use continues to spread into new fields. Recent months saw a surge of interest from biotech researchers, who use the compound in ligand synthesis and bioactive framework assembly. We collaborate with academic labs and contract research firms, leveraging our flexible small-batch production to provide material at custom specs. Our in-house analytics team supports inquiries about rare impurities or process side products, giving academic partners robust reproducibility from one delivery to the next.
In energy materials, especially next-generation battery chemistry, our product finds use in polymer separators and specialty electrolyte additives. Researchers using our materials cite not only the controlled purity, but also traceability and application support, as key reasons to source directly from a proven manufacturer.
Experience on the manufacturer’s side of the aminodiphenylether business teaches the value of open technical exchange. We provide clients with deep-dive technical briefings before first bulk shipments. Our documents don’t just show GC peaks—they provide practical data points gathered over years of scaled operation, so customers can tune synthesis, hazard controls, and application set-up based on evidence, not just claims.
Clients from small research outfits to global conglomerates benefit from this kind of dialogue. By keeping technical, delivery, and after-sales teams tightly integrated, we head off most bottlenecks before they turn into problems. This culture of transparency and hands-on improvement builds trust and supports the collaborative relationships we value most.
Every module in our plant, from batch reactor to final packaging line, embodies the lessons of trial, troubleshooting, and direct feedback. This isn’t abstract—detailed knowledge about how aminodiphenylether forms during reaction, crystallizes, and ships out the door matters more than any certificate or sales talk. Customers return because what they get matches what they expect, not just once, but every time.
Direct engagement with chemical users reveals practical realities. End-use applications—from catalysis to specialty polymer precursors—demand attention to seemingly minor detail. Our teams remain available not just for routine orders but for custom development, troubleshooting, and tailored improvements. Those partnerships, grounded in real manufacturing experience, set us apart.
Anyone can describe aminodiphenylether by formula and a list of properties. Real value comes from knowing the journey of each batch. Machine setbacks, weather disruptions, and even global supply shocks have shaped how we source raw materials, train staff, and ship inventory. Over many years, these experiences teach that quality depends not on a single specification, but on staying connected with the downstream realities our customers face every day.
Each drum of aminodiphenylether has a story. It reflects not just chemical synthesis, but also every improvement made after direct customer feedback, root-cause troubleshooting, and daily operator vigilance. Commitment to reliability defines our outlook and keeps our standards evolving. This practical, hands-on approach to quality and customer partnership underpins every aspect of our aminodiphenylether production. We continue to invest, learn, and improve because our clients’ success—and our reputation—demand nothing less.
