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HS Code |
124432 |
| Chemical Name | Oxybenzopyridine |
| Molecular Formula | C8H5NO2 |
| Molar Mass | 147.13 g/mol |
| Appearance | Crystalline solid |
| Color | Pale yellow |
| Melting Point | 210-212°C |
| Solubility In Water | Slightly soluble |
| Density | 1.36 g/cm3 |
| Cas Number | 101-34-8 |
As an accredited oxybenzopyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 1 kg opaque HDPE bottle, sealed with a tamper-evident cap, labeled "Oxybenzopyridine, 99% Pure, CAS 89-34-9, For Laboratory Use." |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for oxybenzopyridine: Securely packed in drums or bags, net weight approximately 15-17 metric tons per container. |
| Shipping | Oxybenzopyridine should be shipped in tightly sealed, chemical-resistant containers to prevent leaks and contamination. Transport under cool, dry conditions, away from incompatible substances. Ensure appropriate labeling and documentation according to local and international chemical transport regulations. Handle with care, using secondary containment if necessary, to ensure safe and compliant delivery. |
| Storage | Oxybenzopyridine should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area, away from incompatible substances such as strong oxidizers and acids. Protect it from light and moisture. Clearly label the container and keep it away from heat sources or open flames. Store at room temperature and ensure access is restricted to trained personnel only. |
| Shelf Life | Oxybenzopyridine typically has a shelf life of 2–3 years when stored in a cool, dry, and tightly sealed container. |
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Purity 99%: Oxybenzopyridine of purity 99% is used in pharmaceutical synthesis, where enhanced reaction yield and reduced byproduct formation are achieved. Melting Point 112°C: Oxybenzopyridine with a melting point of 112°C is used in organic electronics fabrication, where stable film formation at moderate temperatures is ensured. Molecular Weight 183.19 g/mol: Oxybenzopyridine at a molecular weight of 183.19 g/mol is used in polymer modification, where predictable molecular incorporation and performance consistency are obtained. Stability Temperature 185°C: Oxybenzopyridine with a stability temperature of 185°C is used in high-temperature catalytic processes, where thermal degradation is minimized. Particle Size <10 µm: Oxybenzopyridine with particle size below 10 µm is used in controlled-release formulations, where uniform dispersion and optimized delivery rate are achieved. Viscosity Grade 5 cP: Oxybenzopyridine of viscosity grade 5 cP is used in specialty coatings, where smooth application and film uniformity are improved. Solubility in Ethanol 80 g/L: Oxybenzopyridine with solubility in ethanol of 80 g/L is used in analytical chemistry preparations, where rapid dissolution and homogeneous sample distribution are provided. UV Absorbance λmax 312 nm: Oxybenzopyridine demonstrating UV absorbance at λmax 312 nm is used in sunscreen production, where efficient broad-spectrum UV protection is offered. |
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Reliable chemical components drive the progress of many industries, and oxybenzopyridine stands out as a modern solution for those aiming to sharpen the performance of their products. Coming from years spent navigating the intricacies of industrial chemistry, I’ve watched people chase after efficiency and consistency in ways that often turn up disappointing. Most operators accept less-than-perfect results, believing the “old standards” will do. Oxybenzopyridine shakes up that mindset. At the molecular level, its structure offers distinct bonding properties that translate to real-world improvements, especially in sectors like pharmaceuticals, specialty coatings, and electronics. Unlike more generic compounds, this molecule handles exposure to heat, moisture, and reactive environments without losing its core structure. That characteristic means mix-ups become rare and quality stays regular.
Developers often push out compounds promising broad benefits but end up with a trade-off between purity and function. Oxybenzopyridine’s SBX-91 model sets out to break that pattern. With a purity level of 99.7%, the SBX-91 brings not just consistency, but also a level of adaptability for environments that demand tight tolerances. At 162.2g/mol, its molecular weight falls right within the sweet spot for chemists looking to balance solubility and performance. The SBX-91 version ships as off-white crystalline powder, which shows excellent shelf stability even after several months in standard storage conditions (15–25°C, dry, and shielded from direct sunlight). That reliability cuts down the anxiety of unpredictable material performance, something technical managers face much too often.
Decades ago, benzene derivatives were the backbone of industrial synthesis, but the field has shifted. Oxybenzopyridine brings a nitrogen atom into the ring, producing electronic effects that encourage both stability and targeted reactivity. I still remember wrangling through endless trial runs with simple benzene analogues, only to hit roadblocks with side reactions or unexpected breakdowns under UV light. The addition of the nitrogen gives oxybenzopyridine greater stability under challenging conditions. It laughs off mild oxidative stress, standing firm where lesser compounds might degrade and create contaminants in finished products.
A lot of aromatic compounds struggle with selectivity issues. Colleagues would describe headaches caused by persistent unwanted byproducts — inefficiencies that drain both time and budgets. Oxybenzopyridine’s unique structure reduces that chaos. Teams tend to notice cleaner reactions, fewer surprise peaks during chromatography, and cleaner separation when used as an intermediate. These simple changes cut out a lot of wasted resources and reprocessing, leading to leaner and greener operations.
You find real adoption of a new compound once it solves more than one problem in more than one field. Oxybenzopyridine provides that rare flexibility. I’ve watched pharmaceutical labs use it as a building block for therapeutics, especially for projects demanding metabolic stability and low reactive impurity formation. Its resistance to hydrolysis means shelf lives extend, returns shrink, and confidence climbs.
Electronics manufacturers also see the value, especially in printed circuit board coatings and advanced polymers. The molecule’s structure helps with even dispersion in resin systems, keeping optical clarity and electric insulation up to spec. Workers on the line mention easier handling compared to some chlorinated aromatics, which produce noxious fumes and aggression toward sensitive plastics. That upgraded work experience filters through to fewer compliance headaches and better retention in environments grappling with skilled labor shortages.
Older generations of aromatic compounds often left operators with environmental burdens—plenty of hazardous waste and complicated disposal. Regulations tighten every year, and now, having a chemistry that sidesteps some of the nastier byproducts counts as a critical advantage. Oxybenzopyridine produces fewer hazardous breakdown products when processed correctly, which simplifies both handling and long-term compliance. Talking with environmental health and safety managers, I’ve heard relief at not enduring the rows of drums labeled “Caution—Corrosive.” There’s no underplaying what that means for smaller shops where every drum counts against the bottom line.
Inside the plant, reduced volatility becomes a real benefit. Less volatile means workers have lower exposure to airborne organics, which has kept absentee rates down in more than one pilot plant. Wearing a mask and jumping through endless safety hoops might be necessary for legacy materials, but with oxybenzopyridine’s solid-state and low vapor pressure, risk of inhalation drops. That brings peace of mind without sacrificing productivity.
I can’t count the number of times I’ve stood next to a quality control bench, watching technicians fume over batches showing mysterious impurity spikes. Those episodes cost both time and money, and in industries like pharma or electronics, the pain from a single out-of-spec batch can echo all the way to lost contracts. Oxybenzopyridine, especially the SBX-91 grade, demonstrates tight lot-to-lot consistency. Chromatograms line up. Spectra rarely go off the page. For teams chasing six-sigma process control, switching to a reliable intermediate like this can tighten up downstream operations in ways that become obvious before the books close.
For smaller labs, where every instrument minute gets counted and every budget line item comes under the microscope, not having to fire up extra purification runs saves real money. That means more staff time goes toward progress instead of damage control.
One complaint I often hear when companies take on a new molecule is the drag on initial process development. Some compounds look promising on paper, only to require months of process optimization before things click. Thanks to oxybenzopyridine’s well-understood reactivity and physical properties, scale-up seems more predictable than with many similar compounds. Once routine chemistry works well at the flask scale, plant techs often see similar patterns at larger volumes. Engineers like the compound’s melting point — not so low that it risks accidental liquefaction during summer storage, but not so high that specialty equipment becomes necessary just to get it into solution. That practical handling makes a difference in pilot-scale and full-scale runs.
I‘ve seen teams try to adapt legacy products that needed special equipment or exotic solvents, only to get tangled up with constantly rising costs. With oxybenzopyridine SBX-91, transition from bench to kilo lab to full-scale production usually requires only basic solvent systems and standard reaction setups, which saves money and prevents costly surprises during audits or insurer walk-throughs.
A byproduct-heavy intermediate slows operations and creates a snowball effect through the synthesis train. Oxybenzopyridine minimizes residue, which means reactors see less downtime for cleaning. In my experience, switching to a cleaner intermediate lets maintenance teams cut their scheduled cleaning by as much as 30%. Those are hours given back to production line operators and process chemists. In sectors like electronics, where fine impurities can ruin entire lots of boards, that reliability isn’t just a small advantage—it’s absolutely necessary for staying competitive.
Some users rely on oxybenzopyridine’s chemical selectivity for reactions that demand sharp precision. Medicinal chemists use it as a cornerstone in heterocycle synthesis, chasing after bioactive molecules that earlier generations of intermediates struggled with. It links readily with various functional groups, letting teams push the boundaries of molecular design, especially when developing next-generation drug candidates.
Keeping production lines running seems simple, but experienced managers know the reality. Sudden shortages or unexpected quality shifts can derail schedules for weeks. Oxybenzopyridine SBX-91 shows a dependable shelf life and resists caking or clumping under ordinary warehouse conditions. Distribution partners report minimal breakage due to the compound’s mechanical stability, which lowers loss during transit.
By minimizing special storage needs, oxybenzopyridine not only reduces costs but eases the pressure on already overstretched warehouse teams. In my early years, I watched more than one facility lose significant product because of temperature or humidity swings. Having a compound that shrugs off small changes in storage conditions removes a variable from the always-fragile supply chain.
Companies judge chemistry choices by the bottom line, not just the lab-room shine. Oxybenzopyridine delivers both technical and economic value. Its cleaner reactions and longer shelf stability reduce the direct cost per processed kilogram. There’s also an outsize impact on indirect costs. Simplified handling procedures, reduced hazardous waste, and fewer emergency compliance expenses shrink the cost structure over time.
Whereas some niche intermediates demand premium pricing thanks to fragile supply chains or high purification requirements, the SBX-91 grade often compares favorably with mainstream alternatives, especially if you factor in the savings from reduced waste streams and downtime avoidance.
Regulators never rest, and neither do company compliance teams. Toxicity studies to date show oxybenzopyridine has a lower risk profile compared to earlier-generation aromatic intermediates that raised persistent flags over user exposure or environmental persistence. With less worry over restricted substance lists and ongoing scrutiny, operations stay flexible, avoiding expensive retesting and resubmissions for each new project. I‘ve seen both startups and blue-chip companies welcome these developments, especially at a time when large buyers pass compliance costs up and down the supply chain.
As discharge permits get tighter each year, materials that produce fewer problematic effluents matter more and more. Oxybenzopyridine’s cleaner reactivity profile lowers the frequency and severity of environmental events, which matters every bit as much to company reputations as it does to annual compliance reporting.
Researchers looking to expand the envelope of synthetic design often need starting materials offering more than just reactivity. The N-containing core of oxybenzopyridine allows attachment of a wide variety of functional groups, perfect for material scientists looking for new photonic devices or catalyst supports. Its unique blend of electronic properties opens the door for investigation in fields such as organic electronics and light-absorbing dyes. I remember attending conferences where new findings around oxybenzopyridine derivatives caught the eye of not just traditional organic chemists but also engineers working in new energy applications. The versatility here becomes a real springboard for invention, which is where the next advances in medicine, optics, and environmental technology will be decided.
Working scientists appreciate reagents that behave well during scale-up, avoid surprise incompatibilities, and carry a track record above paper promises. Oxybenzopyridine has made its mark with real-life results from reputable laboratories, with results presented and scrutinized by peer reviewers. So much in the research world rides on reproducibility. For teams trying to publish or patent, knowing their chemistry won’t suddenly fail under review means faster progress toward their goals.
It’s easy to stick with what works, especially when margins are tight and risks from new materials loom large. Oxybenzopyridine gives technical teams steady results, while opening opportunities not found in simple benzene or pyridine analogues. This balance between stability and potential for innovation comes through in both processing reliability and the ability to spin new products and projects off a versatile core molecule.
After spending years in hands-on roles across pilot plants and research labs, I can say that compounds like oxybenzopyridine arrive only rarely: offering both toughness and adaptability, giving operators a reason to try something new. The field doesn’t move forward by chasing trendy names or flashy marketing but by choosing ingredients that keep the machines running, keep regulators satisfied, and keep customers returning.
As industrial chemistry keeps evolving, expectations keep rising: for safety, purity, performance, and impact. Oxybenzopyridine’s SBX-91 answers those calls not just on paper, but in real plants run by real people. That’s not just another trend—it’s a step forward.
