Products

4-Amino-N,N-Dimethylaniline Oxalate

    • Product Name: 4-Amino-N,N-Dimethylaniline Oxalate
    • Alias: p-(Dimethylamino)aniline oxalate
    • Einecs: 223-942-5
    • Mininmum Order: 1 g
    • Factroy Site: Yudu County, Ganzhou, Jiangxi, China
    • Price Inquiry: admin@ascent-chem.com
    • Manufacturer: Ascent Petrochem Holdings Co., Limited
    • CONTACT NOW
    Specifications

    HS Code

    329051

    Chemical Name 4-Amino-N,N-Dimethylaniline Oxalate
    Molecular Formula C8H12N2·C2H2O4
    Molar Mass 252.25 g/mol
    Appearance Light brown to beige crystalline powder
    Cas Number 2662-30-0
    Solubility In Water Soluble
    Melting Point 234-238°C (decomposes)
    Storage Conditions Store at 2-8°C, protected from light
    Purity Typically ≥98%
    Synonyms p-(Dimethylamino)aniline oxalate; N,N-Dimethyl-4-phenylenediamine oxalate
    Hazard Statements May be harmful if swallowed, causes skin and eye irritation

    As an accredited 4-Amino-N,N-Dimethylaniline Oxalate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.

    Packing & Storage
    Packing 250g of 4-Amino-N,N-Dimethylaniline Oxalate is supplied in a sealed, labeled amber glass bottle with safety and handling instructions.
    Shipping 4-Amino-N,N-Dimethylaniline Oxalate is shipped in tightly sealed containers, protected from light and moisture. It is packed in accordance with chemical safety regulations, typically labeled as a laboratory reagent. The package should be handled with care, avoiding extreme temperatures, and shipped according to relevant local, national, and international transport regulations.
    Storage 4-Amino-N,N-Dimethylaniline Oxalate should be stored in a tightly sealed container, away from moisture, heat, and direct sunlight. Keep it in a cool, dry, and well-ventilated area, separated from incompatible substances such as strong oxidizers and acids. Properly label the container and restrict access to trained personnel. Follow all relevant safety guidelines and local regulations for storage and handling.
    Application of 4-Amino-N,N-Dimethylaniline Oxalate

    Purity 98%: 4-Amino-N,N-Dimethylaniline Oxalate with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high reaction yield and product consistency.

    Melting Point 240°C: 4-Amino-N,N-Dimethylaniline Oxalate with melting point 240°C is used in organic electronics manufacturing, where it provides stability during high-temperature processing.

    Molecular Weight 238.26 g/mol: 4-Amino-N,N-Dimethylaniline Oxalate with molecular weight 238.26 g/mol is used in fine chemical production, where it ensures precise stoichiometry in formulations.

    Particle Size <50 μm: 4-Amino-N,N-Dimethylaniline Oxalate with particle size less than 50 μm is used in specialty coatings, where it enables uniform dispersion and smooth application.

    Stability Temperature up to 120°C: 4-Amino-N,N-Dimethylaniline Oxalate with stability temperature up to 120°C is used in analytical reagent preparation, where it maintains chemical integrity during sample processing.

    Water Solubility 10 g/L: 4-Amino-N,N-Dimethylaniline Oxalate with water solubility 10 g/L is used in dye formulation, where it allows for efficient solubilization and consistent coloration.

    Assay ≥99%: 4-Amino-N,N-Dimethylaniline Oxalate with assay ≥99% is used in laboratory research, where it guarantees reliable experimental reproducibility.

    Light Stability High: 4-Amino-N,N-Dimethylaniline Oxalate with high light stability is used in photochemical studies, where it minimizes compound degradation under illumination.

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    Certification & Compliance
    More Introduction

    Understanding 4-Amino-N,N-Dimethylaniline Oxalate: Direct from Our Chemical Plant

    Getting Grounded with Our Product

    For years, our team has worked with 4-Amino-N,N-Dimethylaniline Oxalate, a compound that often doesn’t attract much attention but quietly makes a difference for research labs and specialty chemical processes. Unlike more commoditized amines you find listed on a catalog site, our oxalate salt version comes straight from the same reactors and dryers on which much larger projects ride, giving both the repeatability and traceability that scientists and process engineers actually need. This isn’t just about ticking off a box on a reagent list; in our plant, each batch tells a story about raw material control, operator experience, and real-world troubleshooting during every production run.

    Model and the Path to Consistency

    We produce 4-Amino-N,N-Dimethylaniline Oxalate with attention to particle consistency and ease of measurement. The lot numbers are not a formality. Most researchers want to know what exactly went into the reactor and how tight our controls really are—because one batch’s purity and water content can make or break a synthetic step later. Our technical staff tracks every variable, from purity levels confirmed by HPLC to residual moisture monitoring right before packing. The model is straightforward: batch-to-batch, out of the same stainless reactors, using the same analytic checks. We analyze each run for crystalline structure, appearance, and flow. You see, these might look like technicalities to the outsider, but they matter when it’s your application being tested.

    Specifications Born from Practice

    We don’t just cite specs for the sake of it. Purity in our plant is a hands-on target, not an abstract number. Chemists want to see high purity, but they also ask about color numbers, possible byproducts, solvent residues, or whether any oxidation could sneak in along the way. In our line, average purity runs above 99%, checked using in-house standards and an eye for lot-specific quirks. Moisture levels track consistently under 0.5%. Oxalate forms can cake or pick up water from the air—that’s why we run checks day-in, day-out, no matter how many times we’ve made this material before.

    Daily Usefulness in the Lab and Plant

    Most people who turn to 4-Amino-N,N-Dimethylaniline Oxalate find it isn’t a mainstream purchase. Research teams might need it for intermediates, probes, dye manufacturing, or pharmaceutical R&D. We see it used for analytical reagents too, when a specific salt form gets better solubility, or more predictable reaction profiles. The oxalate salt gives a sharp melting range and keeps out some of the complications that free bases introduce, like volatility or sensitivity to air.

    In real terms, the compound works best when a stable, crystalline powder is needed. As a manufacturer, we’ve learned where things go right and wrong—if you try to swap in the free amine for the oxalate salt, you might get a sticky, hard-to-handle substance that doesn’t deliver consistent stoichiometry or shelf-life. Our teams have chipped in notes that the oxalate salt stores better, dissolves more predictably in standard solvents, and causes fewer headaches during weighing or formulation. That comes from decades making both the salt and the free base, so we don’t talk from a datasheet, but from the floors of our own plant.

    What Sets Us Apart from Other Sources

    Third-party suppliers rarely see a full production cycle. By running every stage ourselves—from raw amine synthesis, to oxalation, drying, and packing—we keep direct control over contaminants and invisible process impurities. Honesty about process limitations helps our clients adapt their methods and avoids surprise rejections during downstream QC. Many vendors repackage bulk stocks. We run continuous checks on NMR signatures, certain UV-Vis properties, and color standards, making sure our product is truly ours and not a relabeled import.

    The plant gets to know how humidity, batch reactor temperature, or even a worn agitator blade can start to change a supposedly routine prep. If we see a spike in residue levels, we call the batch or reprocess under tighter controls, not simply ship with an adjusted label. It sounds unglamorous, but these measures mean when a PhD asks us for reassurance on trace metals or an engineer needs a Certificate of Analysis, we answer directly from our logbooks. We measure batch-specific surface area and make the data available, not because it’s standard, but because previous labs have built better protocols with our help.

    Applications from Direct Feedback

    End users talk to us about where 4-Amino-N,N-Dimethylaniline Oxalate works and—just as often—where it falls short compared to other amines and analog salts. Dye makers like the consistent powder texture, which streamlines blending into early-stage runs for azo or triarylmethane colorants. Analytical chemists told us the extra effort to exclude trace metals pays off with more reliable calibration curves. In pharma R&D, our clients pursue exploratory syntheses using this salt for its stability and measured rate of hydrolysis, noting that oxalate doesn’t introduce the distracting background ions that some other anion forms do.

    Eventually, clients share their tweaks, whether substituting this compound for less stable forms in catalysis, or reducing process waste because they can run reactions at slightly higher concentrations without fouling glassware. Direct communication with academics and process chemists pushes us to keep tightening the upstream steps, so the product evolves from batch notes and feedback rather than only from textbook requirements.

    Comparisons and The Value of Hands-On Manufacturing

    We routinely get asked what sets this salt apart from similar amines or from the hydrochloride and sulfate versions. Those salts sometimes change solubility or add to background noise in analytical runs. The oxalate form offers a better blend of stability and handling for many synthetic applications, and it’s less hygroscopic than its hydrochloride cousin. Technicians report that the oxalate’s crystalline nature leads to less static electricity in packing and easier cleaning of vessels after use.

    Other suppliers may promote the same chemical name, but the difference sits in batch reproducibility, support during troubleshooting, and understanding of the salts' limitations. Years back, a client switched from a generic free base to our oxalate on the recommendation of a research partner. They saw not only tighter yields in their chromatography steps but experienced fewer bottle-to-bottle discrepancies, because our team could dig back into batch records and offer context for every deviation. We operate our synthesis and crystallization equipment for continual output, so each kilogram gets made under the same roof, with raw material incoming checks linked to every output shipment.

    Addressing Challenges in Routine Production

    Producing 4-Amino-N,N-Dimethylaniline Oxalate isn’t just about the chemical equation. Over the years, our staff has faced issues with scale-up, humidity spikes, and even supply chain hiccups on precursor amines. Each challenge created opportunities to finetune our process and reinforce best practices. We introduced inline moisture monitors, developed techniques for gentle handling of the oxalate, and built protocols for maintaining product quality through unexpected plant stops.

    Some of our best improvements came after troubleshooting failed crystallizations or unexpectedly high residue readings. Rather than hiding process setbacks, we document them and share constructive changes with clients. If a run saw nonstandard particle size or shifted melting point profiles, we reach out directly, offering data or reprocessing options. This direct relationship means purchasing staff and researchers don't just receive a product—they get visibility into how the material was made and how it’s evolving.

    No Substitute for Traceability & Support

    Generic products frequently miss the details researchers actually care about: irritant dust, particle flow, the effect of minor contaminants on key reactions. By keeping everything in-house, from amine formation to oxalate crystallization, our plant gives researchers more than a batch code. Over thousands of kilos, really understanding our own supply chain has meant catching potential events before they get out the door, whether it’s a nitrogen leak during neutralization or a temperature spike in the filter press. Traceability isn’t just paperwork—the right QA people know which technician managed each shift and which analytical calibrations confirmed each specification.

    Support staff at our plant discuss results openly with clients, sharing both the ideal and the oddities that come with real-world manufacturing. That might mean tracing back a spike in UV-Vis impurity, or explaining how a certain HPLC peak relates to incoming solvent grade. This day-to-day transparency has won long-term clients, not through slogans but through genuine candor about each batch produced.

    Sustainability, Safety, and Ongoing Responsibility

    Over the past five years, sustainability practices have started to move from buzzwords into real operating requirements. Refining how we make 4-Amino-N,N-Dimethylaniline Oxalate meant scrutinizing solvent usage, recycling water from neutralization, and handling oxalate waste streams safely. Each change gets filtered through regulatory standards, but more importantly, through a duty to protect our team and surrounding community.

    On safety, we invest in continual training—because the people who spend their days in coveralls need more than a reminder about protective gear. They want to understand how this particular salt interacts with air, water, or excess heat in a way that some textbook chemical safety sheet just can’t cover. A routine step in packing can shift into a hazard with the wrong tools or weather, so our teams stay vigilant, learning from close calls and constantly upgrading plant procedures. We run checks, not just because a regulation says so, but because real lives depend on it. That’s something that never gets abstracted into legal fine print.

    Collaborative Problem-Solving

    One of the real strengths of running our own manufacturing comes in responding to client problems as they surface. Sometimes it means altering particle size profiles for a novel application; other times, it’s helping troubleshoot why a formulation solidified unexpectedly. These aren’t generic service tickets—they’re the kind of questions you only get when your team’s phone numbers circulate among actual end users. Over the years, we’ve worked side by side with QC teams, delivering batches personally during pilot campaigns. We believe there’s no substitute for getting feedback straight from the bench or the blending tank.

    This hands-on approach means future process changes use actual user feedback, rather than only internal lab signs. If customers hit a snag, our technical team retraces every reagent, every cooler setting, every drying step, until both parties land on answers. Sharing experience—good and bad—pushes all of us forward, ensuring the next batch not only meets spec, but performs under the real stress and mess of industrial or lab conditions.

    Adapting to Tomorrow’s Needs

    The use cases for 4-Amino-N,N-Dimethylaniline Oxalate keep changing as new research opens different doors—yet the heart of delivering a reliable material never shifts. Whether for dye intermediates, evolving analytical methods, or new medicinal chemistry routes, the close partnership between our shop floor and our clients’ labs keeps demand shifting from one set of properties to another. Sometimes, it means adjusting crystal morphology to prevent caking during summer humidity; other times, optimizing packaging to integrate into fully automated dispensing lines.

    We take pride in tweaking process controls based on where the material is actually headed. Our R&D staff runs side-experiments with tweaks to pH, temperature, or oxalation methods, not just to optimize yield, but to understand real shelf stability and downstream reactivity. The back-and-forth with users—sometimes in the form of sticky notes, sometimes as detailed digital reports—drives process evolution out of the world of theory, right into practical manufacturing.

    Why Direct Manufacturing Matters Even More Today

    A few years back, some researchers began flagging inconsistencies in supposedly identical chemicals from different suppliers. By being the true source, and keeping all process data in-house, we prevent loss of context or introduction of contamination from careless repackaging. The oxalate’s batch reproducibility, known particle size, and trace analytics reassure our partners that each order comes from a single, controlled process—not an unpredictable supply chain. This isn’t abstract—several long-term partners told us their team’s productivity went up once they no longer had to waste time double-checking lots from unknown suppliers.

    The real hidden benefit comes in troubleshooting. As regulatory scrutiny ramps up and new applications surface, end users want more information on processes, possible allergens, and secondary components. Our staff can point to specific logs and run data, giving answers without delay. When a process hiccup arises, plant managers, engineers, and even bench chemists talk directly—no need to hunt for a third-party sales rep or piece together documentation from distant factories. Every time a process or regulatory demand shifts, we stay ready to roll with the change, because our team genuinely knows every batch’s history.

    Building Trust One Batch at a Time

    Every batch of 4-Amino-N,N-Dimethylaniline Oxalate that leaves our plant carries the experience and accountability of our chemical workers and engineers. Over the decades, we have gotten to know the difference: small adjustments in crystalline structure, double checks after unusual humidity, and working with end users to define what “quality” really means for them. That’s not something a trading house or reseller offers. By running our own reactors, sampling our own stock, and recording where every raw material came from, we guarantee a supply chain our own staff can stand behind.

    Ultimately, this approach does more than deliver a chemical. It provides users with the confidence that comes from real facts and hands-on experience. Our doors have always been open to clients who want to learn about our production, request custom tweaks, or just see for themselves how a quality batch gets made. We view every person who uses the materials we make as a partner in shaping the next improvements, forging a cycle of manufacturing experience that yields meaningful results with each batch.

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