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Dimethylamine Hydrochloride

    • Product Name Dimethylamine Hydrochloride
    • Alias Dimethylammonium chloride
    • Einecs 210-048-3
    • Mininmum Order 1 g
    • Factory Site Tengfei Creation Center,55 Jiangjun Avenue, Jiangning District,Nanjing
    • Price Inquiry admin@sinochem-nanjing.com
    • Manufacturer Sinochem Nanjing Corporation
    • CONTACT NOW
    Specifications

    HS Code

    510353

    Chemical Name Dimethylamine Hydrochloride
    Chemical Formula C2H8ClN
    Molecular Weight 81.55 g/mol
    Appearance White crystalline solid
    Odor Amine-like
    Melting Point 171-173°C
    Solubility Soluble in water
    Cas Number 506-59-2
    Boiling Point Decomposes before boiling
    Density 0.95 g/cm³
    Ph 1 Solution 4.5-6.0
    Synonyms DMA HCl, N,N-Dimethylamine hydrochloride

    As an accredited Dimethylamine Hydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.

    Packing & Storage
    Packing Dimethylamine Hydrochloride is packaged in a 500g white, HDPE bottle with a tightly sealed screw cap and clear hazard labeling.
    Shipping Dimethylamine Hydrochloride should be shipped in tightly sealed, clearly labeled containers made of compatible materials. The packaging must comply with local and international regulations for hazardous chemicals. It should be protected from moisture and stored in a cool, dry place. Transport in accordance with UN 2264 classification and applicable safety guidelines.
    Storage Dimethylamine Hydrochloride should be stored in a tightly closed container in a cool, dry, and well-ventilated area, away from incompatible substances such as strong oxidizers and bases. Protect the chemical from moisture and direct sunlight. Ensure proper labeling and keep away from heat sources. Store in accordance with applicable local, state, and federal regulations for chemical storage.
    Application of Dimethylamine Hydrochloride

    Purity 99%: Dimethylamine Hydrochloride with 99% purity is used in pharmaceutical intermediate synthesis, where it ensures high-yield reaction efficiency.

    Melting Point 171°C: Dimethylamine Hydrochloride with a melting point of 171°C is utilized in organic compound formulation, where it guarantees thermal stability during processing.

    Particle Size <100 μm: Dimethylamine Hydrochloride with particle size less than 100 μm is applied in fine chemical reactions, where it provides rapid dissolution and homogeneous mixing.

    Moisture Content <0.2%: Dimethylamine Hydrochloride with moisture content below 0.2% is used in agrochemical manufacturing, where it minimizes unwanted hydrolysis and enhances product consistency.

    Stability Temperature up to 150°C: Dimethylamine Hydrochloride stable up to 150°C is employed in resin production, where it maintains structural integrity during heat-curing processes.

    Assay ≥98.5%: Dimethylamine Hydrochloride with assay not less than 98.5% is essential in dye manufacturing, where it delivers reliable color development and batch reproducibility.

    Low Heavy Metal Content <10 ppm: Dimethylamine Hydrochloride with heavy metal content below 10 ppm is used in food additive precursor production, where it ensures product safety and regulatory compliance.

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    Certification & Compliance
    More Introduction

    Dimethylamine Hydrochloride: Versatile Solutions Start Here

    Dimethylamine Hydrochloride stands as a staple in both lab environments and many industrial settings for good reasons. Anyone who has ever worked on the synthesis of pharmaceuticals or industrial chemicals has probably encountered this compound—it deserves more attention for its reliability and adaptability. With the standard model typically offered as a fine white crystalline powder, Dimethylamine Hydrochloride comes with a clear identity. Chemically, you’ll find it written as (CH3)2NH·HCl, showing a straightforward combination of dimethylamine with hydrochloric acid.

    I’ve seen this chemical put to use in a variety of roles. In API manufacturing, Dimethylamine Hydrochloride often acts as a key intermediate. The tangible impact in this space doesn’t get celebrated enough. Let’s say the task is to synthesize antihistamines or specific antibiotics—more times than not, Dimethylamine Hydrochloride enables those crucial methylation steps. The agility it brings stems from its purity, usually above 99%, and its stable behavior in storage. That’s not something every amine salt can promise. Especially when compared to basic dimethylamine gas, the hydrochloride salt offers a much more manageable form: it’s less volatile, easier to weigh, and not as demanding in terms of safety gear. Over the years, I’ve watched project leads opt for the hydrochloride salt simply because weighing and transferring an odorous, gaseous raw material slows down the entire production floor.

    Specifications That Matter

    Experience has taught me that specifications drive process decisions. Dimethylamine Hydrochloride often hits the sweet spot with a melting point in the low 170s Celsius and virtually no odor. With molecular weight clocking at just under 82 g/mol, its calculations fit seamlessly into stoichiometric planning, saving a lot of unnecessary math headaches. Water solubility goes off the charts—something every chemist nods at, especially in pilot-scale setups where quick and clean dissolution means faster batch turnovers. It stores well, needing only normal ambient conditions and a tight cap; humidity rarely poses problems because the compound resists clumping compared to similar products. And if you run an analytical lab, you learn to value those lots that ship at >99% purity—those always give cleaner, more reliable baseline readings than anything below. Trace impurities get flagged right away in spectral checks, which is why reputable batches get snapped up quickly during large procurement rounds.

    The actual model in use depends on the quantity and granularity needed. Bulk industrial suppliers deliver it in everything from kilo-scale drums to smaller laboratory glass jars. Users in high-throughput settings reach for the multi-kilogram plastic containers since the powder’s density and granulation allow for easy scoop-and-pour handling. For bench research, 500g glass bottles remain a common sight because the product stays free-flowing and avoids reactive contact with moisture or strong bases in the storeroom. Some specialty suppliers offer low-chloride or extra-high-purity versions upon client request, particularly when the downstream synthesis can’t tolerate much sodium or potassium interference. Years ago, we used a custom-milled Dimethylamine Hydrochloride for a radiolabeled tracer project, precisely because the usual off-the-shelf grades didn’t make the analytical cut. End users get real benefits from these adjustments, not just marketing terms; in my view that’s what sets today’s suppliers apart.

    Uses That Reach Beyond the Obvious

    One of the main reasons Dimethylamine Hydrochloride maintains steady demand: versatility. I’ve most often encountered it as a methylating agent or building block. In dye manufacturing, consistent color profiles depend on reliable methylated intermediates—this compound often sits at the center of those reaction cascades. Pharmaceutical companies keep it on hand not just for antihistamines, but also in antimalarial or antiviral synthesis. Its track record for generating clean reaction profiles lets development chemists push speed without trading off endpoint yield or purity. Agricultural chemistry brings up another point—the rise of sophisticated herbicides and pesticides can hinge on ready access to Dimethylamine Hydrochloride since it builds out the tertiary amine backbone found in countless active molecules.

    On the research side, it functions as a pH modulation agent in animal nutrition studies. This application might sound minor, but small pH shifts can change feed digestion rates—precision here makes all the difference in long-term studies. In advanced material science labs, engineers use it to tweak the surface chemistry of carbon-based nanomaterials, giving a hands-on method to tune electronic properties. My colleagues in water treatment also talk about its use in specialty ion-exchange resin preparation. The story is similar everywhere: consistent chemical behavior, manageable storage, and a purity level that fits both bench work and pilot reactors.

    How Dimethylamine Hydrochloride Stands Apart

    Let’s be clear, not all amine salts deserve an equal standing in the lab or plant. Dimethylamine Hydrochloride wins favor because it navigates the line between reactive performance and handling ease. Looking at direct competitors like methylamine or diethylamine hydrochlorides, differences show up immediately in both behavior during reactions and safety protocols. Dimethylamine Hydrochloride avoids the nasty vapor phase releases of methylamine—it’s less likely to trigger unpleasant smells or workplace exposure alarms. On the flip side, diethylamine hydrochloride tends to cake and absorb moisture more aggressively, leading to inconsistent measurements when transferred or weighed. Dimethylamine Hydrochloride’s flowable texture and minimal hygroscopicity help avoid this pitfall all year round, even during muggy summer months. Some specialty chemistries benefit from slightly bulkier amine groups, but for the majority of core organic transformations, the size and reactivity of the dimethylamine group just fit.

    In a strategic sense, this chemical offers peace of mind for logistics teams. It doesn’t require specialty drum linings or ultra-low storage temps. You can plan out procurement months in advance, drop the order into a standard chemical storeroom, and have a product that’s still perfectly usable months later. Logistics planners in pharma call that kind of predictability ‘gold standard,’ especially when global supply lines get tricky. Competing amines often need expedited shipping or risk rapid quality drops; Dimethylamine Hydrochloride just doesn’t demand the same fuss. Lab managers appreciate these subtle but real differences because every last minute counts in production settings.

    Quality, Safety, and User Experience

    From a user perspective, one aspect jumps out: confidence. In my years working in pharma labs, Dimethylamine Hydrochloride never surprised anyone with erratic results. Quality assurance teams see a predictable output in both raw material audits and finished product checks. Standard analytical tools—NMR, HPLC, UV-VIS—read clean, minimizing lost hours in troubleshooting or repeat tests. Unlike finicky amine salts, it stays stable through standard storage—no last-minute runs to re-source materials before a big synthesis run. That means schedules stay tight, project managers stop worrying about mid-cycle expiry dates, and product development flows more smoothly. Teams can focus on the chemistry, not on chasing paperwork or compliance.

    From a safety point of view, the transition from gaseous dimethylamine to the salt form also brings clear benefits. Although all amine-related work deserves attention to gloves, goggles, and vents, hydrochloride salts cut down the handling risks significantly compared to free amines. The solid form resists accidental release and virtually eliminates inhalation worries during normal use. Anyone who’s spilled a small beaker would tell you—clean-up with the hydrochloride powder is simple as opposed to scrubbing away persistent gaseous odors that can linger in the workspace for days. This approach respects both worker safety and lab integrity.

    Challenges and Responsible Use

    No chemical is without its challenges, and Dimethylamine Hydrochloride is no exception. Those working in large-scale operations already know that chloride content might pose corrosion issues for some processing equipment, especially in continuous reactors built with stainless steel grades vulnerable to pits. Keeping tanks and transfer lines clear of lingering chloride residues means regular cleaning and strict protocol adherence—a small but persistent cost in high-throughput settings. This is where engineering teams often work with vendors to find suitable materials or coatings, balancing cost against operational reliability. In my own career, we had to commission special-lined tanks after pressure monitoring showed repeated corrosion hot spots. Taking those lessons forward, proactive monitoring and supplier dialogue always pay dividends in keeping facilities on track.

    Another concern turns up in pharmaceuticals. Regulatory expectations have tightened over the last decade, not just for finished products but for every intermediate. Dimethylamine Hydrochloride, while reliably pure, still needs rigorous lot tracing and contaminant screening. Organizations that value upfront investment in analytical controls come out ahead; even small improvements in batch traceability prevented huge recall headaches for partner labs I’ve worked with. Auditing supplier practices helps to spot weak links early, averting quality lapses that could ripple down the supply chain. More broadly, scientific transparency and detailed documentation support compliance and public health. Trust builds when users know the chemical entering their process is exactly what the label says.

    Values for Sustainability

    Sustainability pressure has grown in recent years, and it shapes procurement decisions too. Dimethylamine Hydrochloride production involves methylation chemistry—a process that smart manufacturers now optimize for reduced emissions and waste output. Factories investing in best-practice vent recovery, solvent recycling, and waste minimization actively build better community and stakeholder relationships. I’ve toured facilities that run on partially renewable energy or employ green chemistry catalysts, and the difference shows. The environmental footprint of this product shrinks further when downstream users line up green procurement policies; that makes a visible impact over time. Groups that take back used packaging or facilitate safe chemical return programs are leading the way.

    Recycling unused product has also come up as a practical issue, since even high-purity lots may outlive their storage windows on the shelf. Close coordination between user groups and hazardous waste contractors is key. Safe neutralization and recycling protocols are not only about ticking off regulatory boxes but about instilling real workplace confidence that all handling—from ordering to disposal—reflects respect for both human and environmental health. Responsible partners share best practices, and those efforts gradually become industry standard. As the chemical economy pivots toward low-waste approaches, Dimethylamine Hydrochloride’s future use will follow progressive firms as examples.

    Enhancing Performance in New Applications

    Innovation doesn’t pause, and Dimethylamine Hydrochloride’s reach now extends into advanced sectors like electronics manufacturing and surfactant research. Semiconductor engineers use the hydrochloride salt to fine-tune etching processes or to help lay down stable layers in thin-film deposition. The compact size of the dimethylamine group helps maintain electrical and chemical harmony on circuit elements, reducing unwanted side reactions. These nuanced effects open up new product lines and support the explosive growth in connected devices. Specialty surfactants derived from this compound also find use in everything from mining slurries to printed paper coatings. Users want streamlining, cost savings, and reduced environmental liabilities—Dimethylamine Hydrochloride adapts smoothly, supporting ongoing product launches while sidestepping more hazardous chemicals.

    In academic centers, graduate researchers test Dimethylamine Hydrochloride in novel catalysts, energy storage prototypes, and even in enzyme mimetic systems. Its stable shelf life and known reactivity cut down on experimental noise, letting researchers hone in on real, publishable results. Some university spinouts have leveraged these properties to prototype greener chemical routes, shrinking the step count and hazard profile for high-value molecules. For these groups, the combination of supplier agility, intellectual property security, and reliable raw material access decides success. In my mentor years, supporting new researchers meant putting trustworthy chemicals like Dimethylamine Hydrochloride front and center; project momentum grew faster because variable control started at the benchtop.

    Supporting Reliable Outcomes in Real-World Settings

    In pilot plants and small-scale manufacturing, the shift from theory to practice often brings headaches. Dimethylamine Hydrochloride’s solid phase, easy solubility, and dependable purity bridge the gap from recipe to reality. Formulation teams don’t have to second-guess density corrections or recalculate safety plans for every run. Instead, they can focus on scaling up with confidence, reducing process drift and product recalls. This focus on everyday efficiency makes the difference for both startups working toward first production and global firms maintaining legacy product portfolios.

    Seasoned operators—those who’ve measured thousands of powders and handled countless raw materials—know that small product touches add up. A slightly less odorous container, a bottle that pours cleanly without caking, a compound that dissolves in seconds: each detail hits workflow speed in ways outsiders might miss. Workplace culture also traces back to product selection. Processes that run smoother, with fewer hitches or unexpected hazards, foster stronger teams and happier, more invested staff. I’ve watched a manufacturing crew switch over to Dimethylamine Hydrochloride from another supplier’s amine salt, only to see error rates and absenteeism drop because tasks and air quality literally improved overnight.

    Looking Ahead: Opportunities for Better Chemical Stewardship

    Modern supply chains face tough scrutiny, both from regulators and from downstream partners who care about safety and quality. Dimethylamine Hydrochloride sits at a crossroads—known for reliability, and increasingly expected to deliver on sustainability and transparency. Industry collaborations that push for cleaner manufacturing lines, smarter packaging, and reduced greenhouse gas outputs will set the agenda. Scientists and buyers demanding batch-level data and traceable origins are shifting the standard. In-house audits, open environmental disclosures, and staff training on proper handling support not just compliance, but event-free operation and workplace morale.

    Continuous improvement remains the watchword. The best chemical partners—those who stand behind every container, answer every oddball query, and invest in genuine safety and environmental upgrades—will win loyalty and long-term contracts. New monitoring technologies, automated batch release systems, and digital transparency all raise the bar for chemicals like Dimethylamine Hydrochloride. As someone who’s tracked product performance from the lab through to finished medicines and coatings, the future lies with those who don’t rest on old wins. Proactive stakeholder feedback, laser focus on operational excellence, and a willingness to pursue the next better process separate leaders from also-rans.

    Closing Perspective

    The story of Dimethylamine Hydrochloride reflects much more than a line in a product catalogue. Its ongoing role in pharmaceuticals, advanced materials, and day-to-day chemistry proves that small details power big results. Whether safeguarding lab workers, supporting researchers, or anchoring global supply chains, this modest chemical has earned its reputation through consistency and adaptability. Firms and individuals who look past buzzword-driven trends and dig deep into material choices put themselves ahead—because in modern science and industry, reliability beats novelty every time. From first-year students to seasoned plant operators, everyone wins when they know exactly what they’re handling and why it matters to the outcome.