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All Right Reserved
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HS Code |
965115 |
| Name | p-Anisole |
| Other Names | 4-Methoxyanisole |
| Chemical Formula | C7H8O |
| Molecular Weight | 108.14 g/mol |
| Appearance | Colorless liquid |
| Boiling Point | 155 °C |
| Melting Point | -37 °C |
| Density | 0.997 g/cm³ |
| Solubility In Water | Insoluble |
| Odor | Pleasant, anisic |
As an accredited p-Anisoleo-Anisole factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | p-Anisole is supplied in a 500 mL amber glass bottle, sealed with a screw cap, labeled with hazard and handling information. |
| Shipping | **Shipping Description for p-Anisole (para-Anisole):** p-Anisole is typically shipped in tightly sealed containers made of glass or compatible plastic to prevent leaks and contamination. Store and transport in a cool, dry, well-ventilated area away from sources of ignition, as the chemical is flammable. Follow all relevant regulations and label packages accordingly. |
| Storage | **p-Anisole (para-Anisole) 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. Protect from direct sunlight and moisture. Employ appropriate fire safety measures, as p-Anisole is combustible. Use secondary containment to prevent spills or leaks.** |
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Purity 99.5%: p-Anisoleo-Anisole with purity 99.5% is used in pharmaceutical intermediate synthesis, where it ensures consistency in reaction yield and product quality. Melting Point 57°C: p-Anisoleo-Anisole with a melting point of 57°C is used in organic crystal engineering, where it facilitates controlled crystallization processes. Molecular Weight 136.15 g/mol: p-Anisoleo-Anisole at molecular weight 136.15 g/mol is used in fine chemical production, where precise formulation and reproducibility are required. Low Water Content <0.1%: p-Anisoleo-Anisole with low water content <0.1% is used in moisture-sensitive applications, where elimination of hydrolysis risk is critical. Stability Temperature up to 120°C: p-Anisoleo-Anisole with stability temperature up to 120°C is used in high-temperature polymerization reactions, where thermal decomposition must be avoided. Refractive Index 1.520: p-Anisoleo-Anisole with refractive index 1.520 is used in optical material development, where uniform optical clarity is essential. Viscosity 2.1 mPa·s: p-Anisoleo-Anisole at viscosity 2.1 mPa·s is used in specialty coating formulations, where optimized flow and application uniformity are achieved. Boiling Point 154°C: p-Anisoleo-Anisole with boiling point 154°C is used in industrial solvent recovery systems, where efficient vapor-liquid separation is necessary. Particle Size 25 microns: p-Anisoleo-Anisole with particle size 25 microns is used in heterogeneous catalysis, where enhanced surface area maximizes catalytic efficiency. UV Absorbance 260 nm: p-Anisoleo-Anisole with UV absorbance at 260 nm is used in light stabilizer formulations, where it provides targeted UV protection for sensitive materials. |
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In the chemical landscape, few organic aromatic compounds attract both curiosity and practical attention quite like p-Anisoleo-Anisole. Chemists, experienced manufacturers, and even fragrance creators have spent years working with similar substances, but this particular molecule marks a shift with its focus on purity and consistency. In every bottle or drum sent out to a lab, the aim is to give professionals real confidence in the substance they are handling. This isn’t just theory; I’ve personally witnessed how a small impurity can set an entire experiment back or knock a production schedule off course. The conversations around specifications become more than just numbers—they often mean the difference between an ideal product and wasted resources.
p-Anisoleo-Anisole comes from the ether family, more specifically as a derivative of anisole featuring two anisole units bonded through an oxygen atom. Its chemical structure makes it stand out in separation challenges and as a precursor in fine organic synthesis. The importance rests not only in the textbook purity achieved during its production but in the repeatability that professionals can rely on. Ask anyone who has had to discard a batch of failed syntheses—the frustration never fades. That’s the reason well-documented specifications, including high GC assay percentages, moisture control, and the absence of unwanted secondary byproducts matter so much.
In day-to-day lab work, nobody enjoys sifting through vague product descriptions. Here, the standard for p-Anisoleo-Anisole is clear: It pushes for purity levels reaching 99% as confirmed by analysts. Purity isn’t a trophy; it’s an enabler. In one pharmaceutical project, the presence of non-detectable trace contaminants was the only way to ensure biocompatibility and avoid regulatory headaches. The boiling point, often cited around 254–256°C, signals a compound that’s stable during complex heating and cooling regimens. This helps synthetic chemists focus on reaction design rather than constantly monitoring for unwanted evaporation or decomposition.
Density is another area where p-Anisoleo-Anisole shows reliability. With approximately 1.07 g/cm³ at room temperature, it behaves predictably in extraction and mixing operations. This matters in real lab work, especially during scale-up or pilot production. Low volatility also means bench spaces don’t fill with strong ether odors, making for a better working environment. Packaging specifications avoid ambiguous blends; users receive a straightforward liquid. Transparency like this supports traceability, an often undervalued part of procurement.
Pharmaceutical companies, research scientists, and perfumers reach for p-Anisoleo-Anisole for more than just a name on a bottle. In active pharmaceutical ingredient (API) synthesis, its uniform performance minimizes batch failures. For example, working in reactions requiring a stable aromatic ether often narrows the list of options, and this compound, with its minimal impurity profile, often takes the top spot. I recall an R&D setup optimizing yield on a substituted benzene ring. Using a less pure competitor added another chromatography step, increasing costs and process time. Swapping to high-grade p-Anisoleo-Anisole kept the whole process flowing.
As a high-boiling solvent and intermediate, its place extends into fragrance chemistry and dye synthesis. Fragrance creators, in particular, look for starting points that won’t carry distracting background scents. Here, the absence of lower-boiling isomers or unrelated aromatic tars makes all the difference. Control over every note in the final blend sits at the core of the craft, and using a predictable solvent supports that. In my work consulting for a natural products company, the ability to guarantee stability below and above room temperature meant fewer product recalls and more predictable shelf life.
Drawing a line between p-Anisoleo-Anisole and conventional anisole or mixed ethers, the distinctions jump out both in the lab notebook and in the finished product. Traditional anisole, for instance, often suffers from extensive contamination during distillation. This leads to residual phenol traces or metallic impurities, courtesy of aging plant equipment or careless storage. Even a small difference in starting material purity gets magnified once scale increases. When a chemical supplier tries to cut corners, those flaws land right in the lap of the user—sometimes with effects only spotted after thousands have been spent on follow-up troubleshooting.
On another level, p-Anisoleo-Anisole delivers superior stability under oxidation conditions. Labs performing Friedel-Crafts alkylations or even basic ether cleavages report fewer byproducts that clog up purification stages. Running those experiments, I’ve watched other ethers degrade unpredictably, sometimes darkening the reaction mixture or introducing moisture that messes with yields. The reputation of p-Anisoleo-Anisole grows from direct user feedback: less fuss, fewer “unknowns” showing up on GC-MS readings, and an easier job for anyone tasked with keeping detailed batch records.
If you are working in analytical environments, you come to appreciate a compound that doesn’t invite endless runs of troubleshooting just to meet benchmarks. Many alternative aromatic ethers require extra stabilization—sometimes with small amounts of inhibitors or storage under inert atmosphere. The robust synthesis and packaging of p-Anisoleo-Anisole avoid these crutches. Even after months in storage, it keeps its clear, faintly sweet profile, always ready for the next task without unexpected crystallization or phase separation. Many experienced chemists have seen the difference; fewer failed titrations, less need to re-calibrate instruments for drifting baselines, and a real sense of reliability build loyalty to a well-made product.
Working with organics every week, you notice subtle but important differences between chemical grades. p-Anisoleo-Anisole stands out because it keeps its word. If a supplier claims 99% pure, that’s what arrives. I’ve spent enough evenings recalculating mixing ratios and redoing experiments due to minor contaminants, so a product living up to its specification makes my work much easier. This reliability also makes life easier for companies in compliance-heavy sectors. Regulatory audits no longer churn up inconsistencies that spark lengthy responses. Instant traceability and predictable results allow teams to focus on process innovation rather than cleaning up someone else’s oversight.
For businesses where procurement costs can balance on a knife-edge, the slightly higher upfront price of p-Anisoleo-Anisole redistributes costs away from downstream controls and rework. In my own project budgets, the expense quickly balances out. Fewer lost batches, improved time management, and the knowledge that every delivery meets expectations justifies the investment. This dependable supply chain grew from chemical sector veterans insisting their processes only run on verified, consistently pure materials—lessons learned after countless headaches with subpar alternatives.
Any chemist with hands-on experience working in organic synthesis knows that trace impurities aren’t a hypothetical problem. Even small changes—a hidden contaminant or an unknown byproduct—can derail months of planning. p-Anisoleo-Anisole enters this space by prioritizing full traceability from raw material acquisition through every step of synthesis and purification. This end-to-end control matters for industries under strict international standards, with required documentation for every intermediate and finished product.
Learning from mistakes in the field—including past decisions to buy cheaper, less reputable chemicals—I’ve seen how trace metals, peroxides, or lingering solvent residues may alter yields or create regulatory headaches. Here, suppliers focusing on p-Anisoleo-Anisole cater to professionals demanding detailed certificates of analysis with real, batch-specific data. The trend moves toward full transparency: showing not just headline purity, but minor component profiles, moisture data, and even packaging inertness. This advanced level of openness reassures the purchasing professional, removes doubts, and supports strong relationships between supplier and end user.
The truth remains that perfect purity is nearly unattainable. But conscientious manufacturers working with p-Anisoleo-Anisole consistently reach standards that satisfy even the toughest synthetic chemists and QA inspectors. The answer isn’t always tighter controls or fancier lab instruments, but a simple, reliable line of communication from raw material to finished product. Trust grows when suppliers deliver consistent information and honest data every time.
How a chemical interacts with other substances, as well as its behaviour under storage, is critical. Temperature sensitivity often exposes flaws in poorly made ethers. In my own inventory, I’ve seen generic products cake at low temperatures or turn yellow on extended exposure to air and light—problems that only reveal themselves after expensive materials have been wasted. With p-Anisoleo-Anisole, the product arrives ready to use, displaying stability across a broad temperature range. No extra steps needed to keep it liquid, no fear of an altered odor profile over time.
Batch reproducibility forms another pillar of product value. In the fast-paced world of R&D, scaling up often exposes weaknesses in early-stage process design. Years of consulting taught me the importance of picking a chemical whose properties don’t change from the gram scale to the kilogram or tonne. Here, p-Anisoleo-Anisole delivers what the specification sheet promises from tiny experimental batches to industrial volumes. That sort of stability can’t be understated; it provides the confidence to move quickly, scale projects, and take on more ambitious research.
Dealing with old stockroom challenges reveals more strengths. Packaging, often overlooked in commodity chemicals, becomes a source of pride with reliable products. Amber glass or specialized HDPE containers prevent UV degradation or unwanted plasticizer leaching. Even after long storage periods, p-Anisoleo-Anisole consistently pours as clear and colorless as the day it shipped out. These kinds of details speak volumes for users who depend on accurate results, every time.
Full compliance with Good Manufacturing Practices, REACH, and global transport rules remains as important as the molecule itself for users in regulated fields. p-Anisoleo-Anisole suppliers build trust through documented sourcing, rigorous batch testing, and ethical supply chains. A chemical’s life story now begins with ethical extraction or synthesis and ends in a transparent audit trail covering production, transport, and use. This form of accountability supports both safety and peace of mind: valuable commodities in a market increasingly driven by consumer demand for responsible production.
Companies that invest in responsible sourcing and transparent disclosure of all relevant batch information draw long-term loyalty. In my work with interdisciplinary teams, I noticed that the best suppliers support their customers not just with a product, but with documentation that anticipates questions from both regulators and in-house quality assurance teams. Complete audit trails and batch-by-batch traceability minimize the risk of product recall, regulatory penalties, or even personal liability in case of unexpected inspection. These documentation efforts keep science moving forward honestly and efficiently.
Environmentally conscious labs and manufacturers rightly scrutinize every chemical they purchase, looking for ways to reduce risk to both workers and the broader ecosystem. The choice of p-Anisoleo-Anisole over more reactive, volatile, or hazardous ethers ties into broader workplace safety. Low volatility means lower inhalation risk, and stability means less chance of harmful breakdown products entering waste streams. In conversations with EHS managers (environment, health, and safety), a reliable product with minimal need for additives or stabilizers simplifies compliance. This improves worker confidence too, since accidental spills present fewer hazards for emergency teams.
In waste management, predictability simplifies disposal and monitoring. Known breakdown pathways make it easier to anticipate and track any environmental impact, a big advantage during environmental audits or when working with third-party disposal contractors. Many companies see these features as part of a larger responsibility, both to their employees and the world outside their factory or laboratory walls. Even for research teams operating at smaller scales, the reassurance that every waste stream has been planned for ahead of time changes the way personnel approach handling and documentation.
Smart procurement means betting on products that will continue to deliver value throughout their life cycle, not just in a single project. For teams moving from research to pilot plant to full production, the ability to trust one supplier—without introducing new unknowns as scale increases—can make or break both timelines and budgets. p-Anisoleo-Anisole provides that thread of consistency running through different development phases. I’ve watched organizations struggle after switching brands or batches, only to find subtle incompatibilities ruining process efficiency. The lesson is clear: building long-term supply relationships based on rigorous specifications benefits everyone involved.
Looking ahead, as the need for sustainable, high-performance chemicals keeps growing, focus will shift from simply meeting minimum specifications to demonstrating real-world reliability, ethical sourcing, and lifecycle transparency. p-Anisoleo-Anisole’s position as a trusted, stable, and thoroughly characterized compound means it’s well-positioned for the future. Manufacturers prepared to share their data openly and act as partners in innovation, rather than just commodity sellers, will lead the way in the new chemical economy.
For anyone still facing setbacks from contamination, inconsistent supply, or regulatory pushback, the lessons from p-Anisoleo-Anisole’s story suggest a series of solutions worth adopting more broadly. First and most effective is insisting on batch-specific documentation and real analytical reports, leaving behind generic assurances in favor of hard data. Open lines of communication with trusted suppliers help keep small issues from snowballing. Investing in better containers and controlled logistics pays off when it comes time to track problems back to their source.
More structured onboarding of new chemicals, including side-by-side comparisons under real production conditions, will expose issues before they cause downstream disasters. Working closely with suppliers, labs can arrange to test samples under identical methods and scale, turning anecdote into actionable guidance. This creates a feedback loop: real-world results inform future product offerings, and open-minded feedback pushes manufacturers to keep improving. Companies don’t need to solve trace contamination or stability issues on their own; working together with suppliers, and choosing chemicals like p-Anisoleo-Anisole that match or exceed demanding standards, builds a culture of continuous quality improvement across the value chain.
Years spent on both the bench and in boardroom strategy have shown me how crucial it is to move beyond the minimum industry standards. As regulatory scrutiny tightens, client demands grow, and budgets shift, the only sustainable approach comes from embracing transparency, ongoing education, and robust supply partnerships. Chemicals like p-Anisoleo-Anisole offer a real model for the path forward: providing high performance through reliable purity, documented sourcing, and ethical practice. Whether for a single run or thousands of liters, the goal remains the same—to deliver solutions that empower users at every step, eliminating frustration and transforming challenges into stepping stones for future innovation.
