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All Right Reserved
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HS Code |
331517 |
| Name | P-Aminobenzamide |
| Synonyms | 4-Aminobenzamide |
| Chemical Formula | C7H8N2O |
| Molecular Weight | 136.15 g/mol |
| Cas Number | 2835-68-9 |
| Appearance | White to off-white crystalline powder |
| Melting Point | 188-190°C |
| Solubility In Water | Slightly soluble |
| Density | 1.32 g/cm³ |
| Pka | 4.70 (amino group) |
| Storage Conditions | Store at room temperature, keep container tightly closed |
As an accredited P-Aminobenzamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | P-Aminobenzamide is packaged in a 100g amber glass bottle with a tight-sealing cap, labeled with hazard warnings and specifications. |
| Shipping | P-Aminobenzamide should be shipped in tightly sealed containers, protected from moisture and light, and labeled according to hazardous material regulations. It must be transported at ambient temperature, avoiding extreme heat or cold. Proper documentation and hazard identification labels are required, ensuring compliance with all applicable chemical shipping and safety standards. |
| Storage | **P-Aminobenzamide** should be stored in a tightly closed container, in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible substances such as strong oxidizers. Keep away from direct sunlight and moisture. For longer-term storage, refrigeration is recommended to maintain stability. Handle with appropriate personal protective equipment and follow relevant safety guidelines. |
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Purity 99%: P-Aminobenzamide with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high yield and minimal impurity formation. Melting Point 156°C: P-Aminobenzamide with a melting point of 156°C is used in organic synthesis reactions, where it improves process consistency under thermal conditions. Particle Size <50 μm: P-Aminobenzamide with particle size less than 50 μm is used in fine chemical formulation, where it enhances dissolution rates. Moisture Content <0.5%: P-Aminobenzamide with moisture content below 0.5% is used in analytical reference standards, where it delivers reliable quantification results. Stability Temperature up to 120°C: P-Aminobenzamide with stability temperature up to 120°C is used in heated reaction processes, where it maintains compound integrity over time. UV Absorbance 280 nm: P-Aminobenzamide with UV absorbance at 280 nm is used in spectrophotometric assays, where it provides accurate compound detection. Molecular Weight 136.15 g/mol: P-Aminobenzamide with molecular weight 136.15 g/mol is used in computational modeling studies, where it ensures precise simulation inputs. |
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P-Aminobenzamide keeps showing up in more corners of modern chemistry, medicine, and research. Some people know it for its work with other compounds, some find it in textbooks, and others just see it on a supplier’s product list. For many in the chemical industry, this compound brings back memories of lab benches, test tubes, and a couple of heated discussions about purity grades. My own path crossed with P-Aminobenzamide during a university research project. We weren’t looking for anything glamorous, just a solid intermediate for building bigger ideas from the bottom up.
P-Aminobenzamide doesn’t parade itself around with flashy branding or wild chemical tricks. Its molecular structure shows a benzene ring studded with an amino group and a carboxamide group locked in at the para position. That’s a technical way of saying this compound is built for stability and purpose—qualities that matter a lot in manufacturing and research. Its chemical formula—C7H8N2O—makes it part of a family you’ll spot in pharmaceuticals, dyes, and analytical reagents.
From my own trials and sourcing headaches, purity always comes up first. If you’re ordering it for a project, you want a clear spec sheet, not a guessing game. Vendors usually offer it in powder or crystalline form, with purity levels hovering around the 98%-99% mark. The color goes from nearly white to pale yellow, sometimes hinting at slight oxidation or minor traces from the process. Each batch, if you’re picky like me, needs a sharp eye because a single wrong supplier can bowl your budget and timeline. I remember one summer spent chasing down the reason for an off-odor in our product, only to discover a bad batch that didn’t quite make the grade.
For as long as people have been tweaking molecular structures, P-Aminobenzamide has quietly underpinned the growth of several key industries. Its big draw lies in how it reacts with other substances to create more complex molecules. If you’ve ever worked in a pharmaceutical synthesis lab, you know the importance of a stable intermediate. Unlike some other compounds, P-Aminobenzamide offers a steady platform, minimizing side reactions and reducing cleanup headaches. This quality alone sets it apart from others in the aminobenzamide family.
Some skeptics used to ask if one could just swap it out for a cheaper or more available substitute. In some settings, that might technically work—until an impurity sneaks in or a yield drops off a cliff. Other isomers, like o-aminobenzamide or m-aminobenzamide, often trip up synthesis steps or don’t provide the same predictable reactivity. If you need reliable results and a consistent yield, cutting corners with a substitute rarely pays off in the long run.
Most conversations about this compound revolve around pharmaceuticals, where it steps in as a core intermediate for building anti-cancer agents, anti-inflammatory drugs, and analgesics. During my first professional stint in the industry, I watched veteran chemists rely on P-Aminobenzamide while working on pain relief compounds. Instead of fussing with less stable alternatives, they stuck to what they knew would deliver a clean transition between synthesis steps.
In dye manufacturing, the story shifts to colorfastness and durability. Chemistry textbooks like to show before-and-after images of dyed fabrics; those results depend a lot on the intermediates chosen in the process. P-Aminobenzamide plays its part here as a key building block in azo dyes, lending a hand in creations that stay put wash after wash. Artisans and industrial manufacturers alike find confidence in the staying power that this intermediate provides.
Analytical chemistry labs also keep steady stocks as a reagent for detecting specific metals or in diagnostic kits. I’ve worked with colleagues who leaned on the robust reactivity of P-Aminobenzamide to pin down elusive compounds from environmental samples. Out in the field or under pressure in a deadline-driven lab, dependable performance counts for everything, and this compound doesn’t disappoint.
Like many organics, P-Aminobenzamide asks for care but doesn’t throw wild surprises. I’ve reviewed the SDS more times than I can count, and the message stays steady. Standard gloves and goggles keep you safe; don’t try to snort the stuff or let it sit on your skin. It melts at a sensible temperature, around 147-150°C, and holds up decently unless you leave it in the open or work in a steamy lab by the coast. Storage in cool, dry conditions keeps degradation at bay. If an accident does happen, standard spill protocols—ventilation and careful cleanup—solve most problems.
Looking back on a botched reaction in grad school, I learned that the real risks come from taking shortcuts with equipment or procedures, not from the chemical itself. Following routine practices turns this product into a partner rather than a hazard.
Every vial or drum of P-Aminobenzamide comes with a handful of measurable specs that shape how it gets used. Solubility matters for process design; it dissolves easily in hot ethanol, which fits most prep routines. In water, the solubility drops but still works with a little coaxing. Each manufacturer might tout a slightly different model, from extra-pure grades to industrial-standard batches. Buyers are wise to seek out certificates of analysis showing HPLC curves, water content, and minimal lot-to-lot variation.
Consistency offers big value for teams running multi-step syntheses on tight budgets. If you’ve dealt with the frustration of mystery variables upending experiments, predictable quality takes on even more meaning. I’ve seen initial skepticism melt away once chemists got a run of consistent batches. Trust doesn’t build overnight, especially with chemicals that form the backbone of specialized drugs or materials.
Many chemical supply houses stock an array of related molecules. It still amazes me how a small change in structure, just swapping an atom’s location, can tank a whole production. Para-aminobenzamide’s layout offers a balance of reactivity and selectivity that other similar compounds can’t match. The ortho variety brings in steric hindrance, which gets in the way for synthesis steps. As for meta-aminobenzamide, you’ll find it less often because it doesn’t deliver the same results for core reactions.
Going down the specialty route, some companies try to push broader applications using generic aminobenzamides. The trouble comes when a customer expects the same performance, only to run into different melting points, lower yields, and tricky purifications. Money wasted, time lost, and a hard lesson learned. The technical community still leans on peer-reviewed studies and real-world data showing that P-Aminobenzamide remains the choice for reliability and compatibility.
Every purchasing decision tells a story. Behind each lab order sits a synthesis plan, a set of rough budgets, and—occasionally—a desperate sprint to find backup suppliers. One season, my team scrambled as a big supplier faced regulatory shutdowns. We turned to smaller, regional sources and learned quickly that not every provider holds up under scrutiny. One shipment, packed poorly, arrived as a caked chunk—not the free-flowing powder we’d ordered. Quality checks, strict batch tracking, and honest vendor relationships became our insurance policy.
For smaller businesses and startups, that lesson hits home. Penny-pinching on a critical intermediate rarely works. I still keep a list of trusted suppliers and set reminders to check in about lot consistency and impurity profiles. Some manufacturers have stepped up their transparency game, providing batch-level data and rapid response to questions about specs and testing. Those who don’t keep up fall off the shortlist fast.
Each pharmaceutical breakthrough starts with the building blocks. P-Aminobenzamide plays a role not just in patents and journal articles but in the slow, unpredictable grind of research. My experience in a biotech startup hinged on developing a pain control molecule; every step, from initial library builds to scaled-up synthesis, demanded solid intermediates. Switching out a dependable compound for an untested alternative slows progress, risks regulatory troubles, and sends morale south.
Some innovators try to tweak legacy syntheses with new reactions, but those projects still come back to tried-and-true intermediates for good reason. Given the sensitive nature of human health products and the strict regulatory environment, only intermediates with a proven track record earn a spot in the toolbox. P-Aminobenzamide checks that box based on decades of published studies, industry consensus, and practical experience from R&D to production batches.
Art and manufacturing share more than most realize. P-Aminobenzamide’s work in dyes stretches from small-scale artisanal work to vast textile factories supplying retail giants. My short stint consulting for a fabric producer exposed the daily demands they face—tight timelines, low tolerance for defective batches, pressure from eco-friendly buyers. A single change in intermediate can mean weeks of extra QC or entire lots rejected based on color shifts.
The thing that earns this compound its spot is consistent color development across production runs. Factories feeding global supply chains can’t gamble on unreliable intermediates. Downstream costs skyrocket if replacement compounds cause binding issues or require more aggressive chemical treatments. With regulations on waste and emissions tightening, manufacturers value intermediates that enable predictable, less resource-intensive processes.
Diagnostic labs run hundreds of samples per day, so each step in the protocol takes on new urgency. P-Aminobenzamide fits into these workflows as a reliable reagent for colorimetric and spot tests. In older methods, and some still favored for their cost-effectiveness, this compound interacts with target substances, often producing color changes easy to see and measure. Technicians rely on its stability during long shifts, confident that their calibration won’t drift due to batch variability.
Having seen colleagues troubleshoot sample preparation routines, I learned just how much difference a stable intermediate can make. Lost time means delayed results and frustrated clients. Finding an alternative with the same practical performance isn’t easy, especially for cash-strapped public labs. They’d rather stick with established, well-documented chemicals than risk a failed round of external proficiency testing.
Innovation in chemistry keeps shifting to precise, more efficient syntheses requiring specialized intermediates. While some trends lean toward greener, safer alternatives, adoption takes time and careful validation. P-Aminobenzamide stands out as a bridging compound. Its established role shortens regulatory review and encourages researchers to design new pathways with more confidence. I recently sat in on a virtual conference where chemists debated the merits of exotic new reagents, yet by the end, most agreed their core work still leaned on classics like this one.
Researchers juggling multiple priorities—performance, cost, reproducibility—tend to reach for well-documented, predictable substances. The pressure to develop faster, safer pharmaceuticals or more sustainable dyes doesn’t eliminate the need for intermediates proven in real-world production. If anything, the new sustainability goals make batch quality, waste minimization, and process predictability more vital.
A few persistent hurdles show up for anyone using or buying P-Aminobenzamide: inconsistent quality from smaller suppliers, limited environmental information for buyers wanting to minimize their impact, and the challenge of handling recent regulatory changes. From my vantage point, the best solution usually involves open communication—chemists, suppliers, and regulators all pulling together to share data and improve standards.
Some suppliers now post batch-level analytics and traceability info online. That works for seasoned buyers and newcomers alike. Industry groups have started publishing updates on best practices for handling and storing compounds like P-Aminobenzamide, keeping everyone on the same page. Collaborative purchasing networks help small labs get affordable, reliable supplies by pooling their orders and screening providers. And more labs now keep better records and cross-check each shipment’s paperwork against internal benchmarks—no more lost time wondering what went wrong.
The more I’ve worked with P-Aminobenzamide, the more respect I have for how much manual oversight goes into each batch that leaves a reliable supplier. Regulators, for their part, have started to recognize certain intermediates as “essential” for continued medical and industrial progress, shaping export guidelines and customs policies. Given the massive cost and hassle of shifting to new intermediates mid-stream, most end users advocate strongly for stability and clear product documentation.
It’s easy to lose sight of the human side of what seems like a commodity product. Every small improvement in batch purity, every fresh data sheet, every conversation with a vendor saves somebody hours of troubleshooting and budget wrangling. The digital age—cloud databases, real-time analytics, and rapid feedback—has started to lift the veil on supply chains. Instead of flying blind, more buyers and researchers can make fact-driven choices from the moment they select P-Aminobenzamide for their work.
P-Aminobenzamide doesn’t make headlines, but it shapes thousands of stories behind the scenes. There’s a quiet pride in using a chemical that holds up under close scrutiny, that can be counted on to deliver performance day in and day out. My time spent sourcing, testing, and using this compound makes me believe that reliability outweighs hype. The factories, labs, and research centers where I’ve worked all needed a backbone of stable, trusted intermediates. P-Aminobenzamide fills that role, not just as a product on a shelf, but as an enabler of progress that shows up in finished medicines and durable dyes.
As the demands of science and industry change, the value of integrity—both in products and in people—doesn’t fade. Transparency, experience, and a willingness to learn drive better choices. For now, and for the years ahead, I see P-Aminobenzamide continuing to do what it does best: offering a foundation for building, creating, and solving problems where consistency and trust matter more than ever.
