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HS Code |
259193 |
| Chemicalname | 4-Amino-2-Nitro-N-Hydroxyethylaniline |
| Casnumber | 3886-56-2 |
| Molecularformula | C8H11N3O3 |
| Molecularweight | 197.19 g/mol |
| Appearance | Yellow to orange powder |
| Solubility | Soluble in water and ethanol |
| Meltingpoint | 132-135 °C |
| Purity | Typically >98% |
| Synonyms | 4-Amino-2-nitro-N-(2-hydroxyethyl)aniline |
| Storageconditions | Store at 2-8°C, keep container tightly closed |
As an accredited 4-Amino-2-Nitro-N-Hydroxyethylaniline factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 250g of 4-Amino-2-Nitro-N-Hydroxyethylaniline, securely sealed in an amber glass bottle, labeled with hazard warnings and product details. |
| Shipping | 4-Amino-2-Nitro-N-Hydroxyethylaniline should be shipped in tightly sealed containers, protected from light, moisture, and incompatible materials. It must be handled as a hazardous chemical and packed according to local and international regulations for transport. Appropriate labeling and documentation are required to ensure safe handling during shipping and delivery. |
| Storage | Store **4-Amino-2-Nitro-N-Hydroxyethylaniline** in a tightly sealed container, protected from light and moisture, in a cool, dry, and well-ventilated area. Keep away from incompatible substances such as strong oxidizers and acids. Use appropriate chemical storage cabinets, label properly, and ensure access is restricted to trained personnel. Follow all safety and handling guidelines as outlined in the Material Safety Data Sheet (MSDS). |
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Purity 99%: 4-Amino-2-Nitro-N-Hydroxyethylaniline of 99% purity is used in pharmaceutical intermediate synthesis, where high chemical purity ensures optimal yield and minimal byproduct formation. Molecular weight 199.18 g/mol: 4-Amino-2-Nitro-N-Hydroxyethylaniline with a molecular weight of 199.18 g/mol is used in specialty dye production, where precise stoichiometry enables consistent coloration. Melting point 160°C: 4-Amino-2-Nitro-N-Hydroxyethylaniline with a melting point of 160°C is used in solid-state formulation development, where thermal stability ensures reliable processing conditions. Particle size D90 <50 µm: 4-Amino-2-Nitro-N-Hydroxyethylaniline with particle size D90 less than 50 micrometers is used in pigment dispersion, where fine particle size results in improved homogeneity and color fastness. Stability temperature 120°C: 4-Amino-2-Nitro-N-Hydroxyethylaniline stable up to 120°C is used in high-temperature inkjet ink manufacturing, where thermal resistance minimizes degradation during production. Aqueous solubility 80 mg/mL: 4-Amino-2-Nitro-N-Hydroxyethylaniline with aqueous solubility of 80 mg/mL is used in water-based cosmetic formulations, where increased solubility ensures efficient blending and application. |
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Most people outside the chemical field might be surprised how a single compound like 4-Amino-2-Nitro-N-Hydroxyethylaniline can impact a range of industries. Chemists appreciate it for more than just its tongue-twisting name. Working with specialty chemicals for a few years, I've seen firsthand how these molecules become building blocks, moving from shelves and storerooms into dyes, pharmaceuticals, and sometimes even something as pedestrian as a ballpoint pen ink. We tend to overlook the intricate development behind something so small, but each compound, including this one, opens doors that didn’t exist before.
Plenty of chemicals crowd the market, each one vying for a spot in a crowded toolbox. The molecular design of 4-Amino-2-Nitro-N-Hydroxyethylaniline stands out with its unique combination: an amino group, a nitro group, and a hydroxyethyl chain all bound to the aniline backbone. This subtle blend leads to properties you won’t find by settling for your standard aniline derivatives. From my time in a research lab, I can say no two dyes behave the same way, and even small tweaks to the molecular make-up can shift color stability, lightfastness, or solubility. The functional groups in this compound aren’t just decorative — they shape interactions in whatever system you add the compound to.
Many who work in synthesis know the headaches: inconsistency, poor reactivity, or processing problems due to unpredictable impurity levels. The market often crowds itself with cheaper alternatives, but cutting corners there means living with frequent batch failures. 4-Amino-2-Nitro-N-Hydroxyethylaniline often comes with better purity profiles, cutting down on those agonizing lab reruns. In the competitive world of chemical manufacturing, those cost savings add up, sometimes deciding which plant stays open or closes for good.
Most research points toward this molecule’s dominant role in dye and pigment manufacturing. Dye-making is never as simple as just mixing colors; it’s chemistry at the molecular level, where stability and shade fidelity separate winners from the forgettable. My own experience in a textile company showed me the value of a reliable chemical intermediary. A molecule like 4-Amino-2-Nitro-N-Hydroxyethylaniline brings a rare balance, acting as both an electron donor and acceptor. In dye synthesis, this dual ability introduces greater flexibility, especially when looking for target shades or strong colorfastness.
The compound’s structure, with both hydroxy and amino functional groups, channel reactivity in useful directions. For dye manufacturers, this means more vivid colors with better wash and light stability. Chemists exploit the nitro group’s electron-withdrawing power to fine-tune how deep and strong the hues get, achieving vivid tones that hold under repeated cleaning cycles or sunlight. Competition in the textile industry is relentless. We needed every edge for our finished products, whether supplying the sneaker world or luxury upholstery. Every time a batch faded quickly, it wasn’t just a chemical failing; it was a loss of trust between us, our customers, and the brands on store shelves.
Pigment applications benefit as well. Some companies find standard aromatic amines too unstable when exposed to light or acidic environments. Adding the hydroxyethyl moiety in 4-Amino-2-Nitro-N-Hydroxyethylaniline gives better resistance. The pigment doesn’t break down as easily, reducing waste and extending shelf life. In the coatings market, these perks can make or break a formulation. My own time consulting with paint manufacturers drove home the point — even half a percent increase in pigment stability saves tons of raw material and helps built-for-purpose coatings survive actual wear and tear, not just lab tests.
The pharmaceutical world rarely stands still; new targets and synthetic challenges appear almost daily. In drug discovery, specialty compounds like 4-Amino-2-Nitro-N-Hydroxyethylaniline aren’t usually the endpoint but part of the synthetic route. The hydroxyethyl arm opens doors in making more soluble drug precursors. From my early days working on small-molecule synthesis, I remember the scramble when a key intermediate wasn’t soluble enough, sending us down weeks of solubility enhancing chemistry just to make an intractable molecule workable.
This compound’s design helps sidestep those nightmares. Its mix of polar groups creates paths for further functionalization. That means medicinal chemists get a scaffold adaptable to many final targets, without retrofitting the process each time. Nitro and amino moieties can be chemically transformed into a wide array of other functionalities: reducing the nitro to an amine, or using the hydroxy group as a handle for attaching larger groups. I’ve seen clever teams use compounds like this one to speed up the journey from a vague idea in a patent planning meeting to an actual candidate on the testing bench.
While not a blockbuster drug material itself, 4-Amino-2-Nitro-N-Hydroxyethylaniline enters the process when flexibility is needed most. The pharmaceutical development pipeline rewards raw materials that bring reliability, safety, and clean outcomes. Fewer byproducts and predictable reactions cut regulatory hassle and let research groups focus where it counts: on innovation, not on chasing down unknown contaminants.
Good chemistry doesn’t just depend on molecules; it thrives because of standards. Over the years, process chemists have demanded higher quality and traceability for their chemical feedstocks. My stint reviewing quality audits showed how even a small inconsistency in raw material purity can snowball into lost batches and supply chain headaches. The companies that produce 4-Amino-2-Nitro-N-Hydroxyethylaniline to modern standards emphasize batch consistency, low levels of trace metals, and reliable packaging. Those details stay invisible to the outside world but mean everything behind the scenes.
Some compounds, even with promising properties, slip in and out of favor because they don’t survive the scrutiny of modern safety and regulatory reviews. With technology and instrumentation advancing, labs now spot trace-level impurities that would’ve passed unnoticed years ago. Those improvements have bumped expectations up a notch. Any product aiming for the widest user base must prove rock-solid reliability not just in specs, but in the real world. Rooting out process impurities, cutting residual solvents, and keeping contaminants in check all trace back to fundamental expertise and the discipline of the workforce.
The most trusted specialty chemicals often carry a map of their manufacturing lineage. Every operator, every supplier, and every test gets documented so end users can trust each batch — no easy feat in a globalized market with raw ingredients zigzagging across continents. Transparent sourcing and concrete production data become safety nets for buyers, chemists, and the companies who carry liability for finished products. Many recalls and high-profile failures stem from lax documentation, a lesson few want to learn twice.
Anyone picking a chemical for their process faces a jungle of options. The standard lineup of aniline derivatives can offer similar baseline functions, but the real differences come at the limits. Some like para-phenylenediamine (PPD) offer affordability but bring allergen concerns and less color stability. Others, like ortho- or meta-nitroaniline, can limit process flexibility or fail in demanding conditions.
The structural tweak in 4-Amino-2-Nitro-N-Hydroxyethylaniline avoids many hang-ups. By drawing on both electron-rich and electron-poor portions within a single molecule, chemists can push reactions in more directions. For example, I saw a big client fight constant delays using a more rigid aniline-based pigment in their inkjet formulation. Their switch to a hydroxyethylated aniline moved them out of a rut. No more pipe clogs, better shelf life, and improved print clarity. The difference wasn’t marketing fluff; it changed their margins and made life easier on their technical staff.
It's tempting to ignore incrementally better molecules in favor of what’s familiar. Yet, those incremental wins — a percent less waste here, a few days longer shelf life there, easier downstream handling — all add up. When looking across the range of similar compounds, few offered the same blend of functional versatility and practical reliability in the systems where toughness mattered.
Dealing with specialty organics always calls for respect and caution, both for personal health and the wider environment. Through the years, I’ve seen how improved handling protocols and clear information keep accidents at bay. 4-Amino-2-Nitro-N-Hydroxyethylaniline isn’t a bulk commodity handled by thousands daily, but labs and small plants count on safety data and experience-based best practices.
Technical staff appreciate clear labeling and packaging; it cuts confusion during storage or transfer into a reactor. The industry has moved past the days of nondescript drums and guesswork; today’s users expect not just basic hazard statements, but the backstory — how it was made, which lot it came from, who tested it, and what they found. These expectations aren’t just box-ticking for regulations; they shield workers and the environment from known and unknown harms. Even experienced chemists take mishaps personally, and the reputation of a chemical supplier often lives or dies by those close calls.
Waste management can no longer sit as an afterthought. Most organizations have grown more conscious about limiting effluent toxicity and improving recovery. With tighter rules on landfills, air emissions, and water discharge, process planners now run lifecycle analyses for every significant raw material. 4-Amino-2-Nitro-N-Hydroxyethylaniline’s better purity at source gives downstream handlers fewer surprises. Less unexpected waste means less troubleshooting and a smoother production line.
Growing up watching the chemical industry cycle between boom years and public backlash left a strong impression on me. Public opinion around specialty chemicals is evolving, driven by real-world outcomes like water safety, air quality, and workplace exposure. Materials that once passed muster now face critical scrutiny. Specialty chemicals aren’t immune; buyers increasingly demand greener synthesis routes, lower residual toxicity, and better end-of-life options.
4-Amino-2-Nitro-N-Hydroxyethylaniline shows what progress can look like. It’s not the greenest compound possible, but ongoing advances in production routes have reduced hazardous reagents and cut down on waste. Some plants recover more solvents and raw intermediates than ever before. My own run-ins with waste reduction programs showed a clear payoff — shifting to processes with lower environmental burdens didn’t just score points with regulators, it slashed costs by minimizing waste handling and reducing raw material purchases.
Looking ahead, suppliers have begun partnering with academics and process engineers to squeeze more efficiency and sustainability out of tried-and-true molecules. Sometimes that means retooling the synthesis, sometimes it’s about integrating catalysts that shave off steps and shrink emissions. Stepping outside the box of business-as-usual pays off. Forward-thinking manufacturers prove that specialty molecules like this can thrive in a market increasingly defined by strict standards and public trust.
The chemical sector faces distinct hurdles: regulatory churn, tech advances, environmental rules, and unrelenting price competition. For people on the frontline, the right raw material can be an anchor. Yet, stubborn barriers remain: sometimes buyers lack technical support, batch data turns up incomplete, or new synthesis asks for revalidation each time a tiny change creeps in.
More dialogue between users and suppliers would solve daily frustrations far better than top-down directives. For years, I saw what happens when chemists and purchasers trade notes with makers: feedback would roll back into the product, fostering transparency, reliability, and mutual trust. Even small pilot programs that allowed hands-on trials cut weeks out of troubleshooting cycles. Building those relationships up and down the chain keeps the whole ecosystem strong.
A second lever involves investing in technical support. Many facilities run lean, always hunting for qualified people who can train others, troubleshoot problems, and connect the dots between raw materials and process performance. The best specialty chemical suppliers do more than just ship orders: they field questions, walk through troubleshooting, and share data openly. Good support teams work with users to keep up with regulations, find greener options, and carry forward lessons learned at scale.
Finally, the drive for sustainability in specialty chemicals can’t succeed on good intentions alone. Industry groups, educators, and buyers need to keep learning from each other. Stakeholder validation — real, rubber-meets-road testing with transparent data — proves more effective than simply following regulations. My mentors taught me to keep asking: how does this chemical stack up, not just on cost or paperwork, but on impact and reliability where it matters? The answer almost always comes from broader engagement, not one-way declarations.
Trust marks the real differentiator in chemicals today — and nobody builds trust with fine print on a website. After decades spent listening to chemists, production leads, and environmental managers, it's clear that products like 4-Amino-2-Nitro-N-Hydroxyethylaniline earn their keep by delivering in challenging circumstances, process after process. Relying on proven batches, traceable origins, and technical openness, the best suppliers make new research feasible and high-quality manufacturing repeatable.
The technical leaps in chemistry ultimately rely on incremental wins — one more reliable bond, one less waste stream, one more successful reaction out of the crucible. If specialty molecule producers keep tuning their approach toward open communication, rigorous control, and genuine partnership, every user stands to benefit. There's no magic compound that solves every challenge, but with molecules as adaptable as 4-Amino-2-Nitro-N-Hydroxyethylaniline, the stage stays set for progress in science, industry, and sustainable manufacturing. In the end, it’s the application, not just the molecule, that counts — and getting the right material, at the right time, in the right hands, is what keeps the whole system moving forward.