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HS Code |
642534 |
| Product Name | 4,6-Diaminoresorcinol Dihydrochloride |
| Cas Number | 2719-27-9 |
| Molecular Formula | C6H10Cl2N2O2 |
| Molecular Weight | 213.07 g/mol |
| Appearance | Light yellow to tan powder |
| Melting Point | 246-249°C (dec.) |
| Solubility | Soluble in water |
| Purity | Typically ≥98% |
| Synonyms | 1,3-Benzenediol, 4,6-diamino-, dihydrochloride |
| Storage Conditions | Store at 2-8°C, keep tightly closed |
| Chemical Structure | Benzene ring with amino groups at positions 4 and 6, hydroxyl groups at positions 1 and 3, as dihydrochloride salt |
| Ec Number | 220-347-4 |
As an accredited 4,6-Diaminoresorcinol Dihydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging contains 25g of 4,6-Diaminoresorcinol Dihydrochloride in a tightly sealed amber glass bottle with a secure screw cap. |
| Shipping | 4,6-Diaminoresorcinol Dihydrochloride is shipped in tightly sealed, chemically resistant containers to protect from moisture, light, and contamination. Transportation complies with relevant safety regulations, including labeling for hazardous materials if required. It is kept at controlled temperatures and away from incompatible substances, ensuring safety and product integrity during transit. |
| Storage | 4,6-Diaminoresorcinol Dihydrochloride should be stored in a tightly closed container, in a cool, dry, and well-ventilated area away from incompatible substances such as strong oxidizers. Protect from light and moisture. Store at room temperature, avoiding excessive heat. Ensure proper labeling and restrict access to authorized personnel. Follow all relevant safety and regulatory guidelines during storage. |
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Purity 98%: 4,6-Diaminoresorcinol Dihydrochloride with 98% purity is used in pharmaceutical intermediate synthesis, where high chemical yield and selectivity are achieved. Molecular Weight 211.07 g/mol: 4,6-Diaminoresorcinol Dihydrochloride of 211.07 g/mol molecular weight is used in organic dye manufacturing, where consistent pigment quality is maintained. Melting Point 234°C: 4,6-Diaminoresorcinol Dihydrochloride with a melting point of 234°C is used in thermal-resistant polymer formulation, where enhanced thermal stability is provided. Particle Size <50 μm: 4,6-Diaminoresorcinol Dihydrochloride with particle size under 50 μm is used in specialty resin production, where superior dispersion and uniform matrix integration occur. Stability Temperature up to 80°C: 4,6-Diaminoresorcinol Dihydrochloride stabilized up to 80°C is used in diagnostic reagent development, where robust performance across temperature ranges is ensured. Aqueous Solubility 10 mg/mL: 4,6-Diaminoresorcinol Dihydrochloride with aqueous solubility at 10 mg/mL is used in biochemical assay preparation, where rapid and complete dissolution is critical. Chloride Content ≤13%: 4,6-Diaminoresorcinol Dihydrochloride with chloride content ≤13% is used in cosmetic dye precursor synthesis, where minimized side-reactions are guaranteed. |
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Many people in research and industry tend to focus on headline-grabbers—big-ticket compounds or the latest brand-new catalyst. But if you scratch beneath the surface in the labs where real progress happens, you’ll find specialized chemicals like 4,6-Diaminoresorcinol Dihydrochloride quietly doing essential work. In my own experience, a compound like this reflects the best traditions of scientific craftsmanship: It serves a specialized purpose, contains precisely defined chemistry, and sits at the center of both daily routine and the creative process of innovation.
At first glance, 4,6-diaminoresorcinol dihydrochloride looks like a simple organic compound—after all, it’s classified as an aromatic diamine. Yet, a closer examination reveals real value. Its structure features amino groups at the 4 and 6 positions on a resorcinol backbone, further stabilized by two hydrochloride groups. This molecule’s physical properties and chemical stability lend it value for both researchers and manufacturers who rely on consistent results year after year. Reliable data from reputable suppliers list the product as a fine crystalline material with a high degree of purity, soluble in water, and known for its stability under everyday storage conditions.
A scientist’s perspective always takes into account the workflow. For me, the thing that distinguishes 4,6-diaminoresorcinol dihydrochloride is the flexibility it provides when synthesizing specialty dyes, pharmaceuticals, and bioactive small molecules. When dealing with diazotization reactions, researchers often reach for this compound because the two amino groups allow selective modification not achievable with single-amino analogues. In dye chemistry, it joins coupling components to build vibrant, stable colorants. This work matters: The textile and printing industries both depend on reliable color performance, which starts from the fine details of compounds like this one. In my graduate studies years ago, I spent long hours running controls to measure shade consistency. Trustworthy intermediates made that work possible.
Many chemicals compete for attention in the same synthetic spaces. Try using resorcinol without substitution, or a common monoaminophenol, and the results shift. You might find lower yields, different solubility, or complications during purification. With diaminoresorcinol, the specific pattern of amino groups makes it a more reactive participant in certain coupling and polymerization steps, granting access to structures other similar aromatic compounds can’t reach efficiently. It’s tempting to grab a cheaper or more abundant substitute, but the right fit can make all the difference between repeatable science and hours lost hunting for where things went wrong. I recall conversations with bench colleagues who learned this the hard way—one batch switched for a monoamine meant weeks of setbacks and extra troubleshooting.
Consistency and purity are not mere buzzwords here—they’re the lifeblood of success in chemical work, even if advertising copy tends to overuse the terms. I learned early in my career that high-purity 4,6-diaminoresorcinol dihydrochloride helps avoid the headaches of impurities and side products in both small-scale reactions and scaled-up manufacturing. Not all sources are alike. Some batches come with persistent inorganic contamination or variable moisture. Trusted suppliers typically guarantee high-purity standards, as verified by melting point analysis, NMR, and chromatographic tests. These controls, grounded in the practices recommended by the International Council for Harmonisation and reflected in United States Pharmacopeia guidelines, support everything from fundamental synthetic experiments to pharmaceutical ingredient production.
In my laboratory days, setting up a synthesis with 4,6-diaminoresorcinol dihydrochloride called for rigorous planning. Proper storage—sealed containers, away from light and moisture—helps ensure the powder stays pristine. It dissolves readily in water, creating homogeneous solutions that mix well for batch reactions. That property saves hours compared to some other aromatic amines prone to clumping or stubborn undissolved lumps. Because its two amino groups facilitate targeted functionalization, chemists regularly design new libraries of compounds starting with this precise backbone. These custom molecules are used in screening for new antibiotics or designing safer color additives for industrial use.
People not involved in specialty chemical procurement may shrug at the idea of such a niche product having an impact. But seeing the detail and care that goes into choosing 4,6-diaminoresorcinol dihydrochloride made me appreciate the broader story—how even a teaspoon of the right material can unlock whole new lines of research. My own projects benefitted at times from those obscure ingredients I remembered signing off for purchase months earlier. The whole supply chain—chemical engineers, quality control staff, shipping specialists—gets involved to make it all possible. As a user, you know how much effort and know-how sits behind the label.
One area that shapes the journey of any chemical, and particularly ones like 4,6-diaminoresorcinol dihydrochloride, is the regulatory environment. It must meet established criteria for purity and safety, outlined by international and national organizations, before entering the pharmaceutical or dye-making ecosystem. In my experience, adhering to these checks prevents future roadblocks, whether for purchasing agents or compliance officers. Rigorous tracking—from raw material receipt to finished product testing—means less risk of hazardous batch failure or regulatory issues down the line. For those of us who have managed a laboratory audit, this kind of traceability feels indispensable. No one likes backtracking across six months of records only to find a supply chain misstep could have been avoided at the outset.
Every specialty chemical poses its own supply and handling puzzles. Sourcing high-quality 4,6-diaminoresorcinol dihydrochloride sometimes exposes gaps in global supply lines, as production tends to cluster in a few facilities equipped to ensure the extremely high levels of purity required. Diversifying suppliers and developing relationships with dependable producers pays off in the long run. Many larger labs now rely on multiple sourcing agreements and maintain robust in-house quality verification before accepting new batches. For smaller organizations, partnering with university consortia helps pool demand and achieve leverage with suppliers—in my own work, these collaborations often unlocked access to better grades of material and reduced cost per gram.
Beyond supply, keeping accurate and detailed documentation at every step stands out as a foundational practice. Product certificates showing lot-specific data help chemists interpret their results and spot any deviations early. Material safety data sheets—offered by reputable suppliers—give labs a clear guide to safe storage, handling, and emergency procedures. I’ve seen more than one project stall because a researcher ignored the documentation or missed a key supplier note about shelf life or sensitive impurities. In my own workflow, cross-checking these sources became a daily routine, especially as a project approached a regulatory milestone. Over time, this habit proved its worth by preventing small hiccups from turning into time-consuming product recalls or wasted experimental runs.
Most write-ups focus on major commercial uses such as dyes and pharmaceuticals but the list does not end there. Lab teams working in academic and government environments recognize the value of 4,6-diaminoresorcinol dihydrochloride in catalyst development or sensor technology. The compound’s two amine groups open new approaches to immobilizing metals or building scaffold materials. A team I once advised leveraged these features to anchor palladium in reusable cross-coupling catalysts, making a real impact on sustainability metrics for industrial chemistry programs. Some innovative polymer chemists use it to tweak the electrical properties of certain plastic blends—important work for building safer batteries or more sensitive diagnostic tools.
Getting consistent quality over multiple batches remains a real challenge, especially when demand rises or sourcing shifts internationally. Some laboratories implement rigorous incoming goods inspection, including retesting the melting point and composition for new containers, regardless of the supplier’s certification. From my own perspective, running a small-scale test reaction on each new lot before ramping up saved both time and costly materials. Large facilities often employ automated tracking systems to link each gram used in research to the original lot number—a practice I admire for its transparency and regulatory alignment, though it sometimes adds paperwork.
No commentary on a chemical’s role in modern science should ignore the broader picture. Ensuring safe lab work does not end with hazard labeling; it means actively adopting good laboratory practices (GLP) and protective measures. This compound, like most aromatic amines, requires careful handling to avoid unnecessary exposure. Labs use local exhaust and containment to limit airborne dust, and train staff on rapid cleanup in case of spills. Disposal routes, strictly following local and international guidance, keep hazardous waste out of the environment. For those of us raised before the current wave of environmental reforms, today’s stricter oversight feels entirely appropriate. Those minor procedural changes—disposable gloves, fume hoods, clearer warning labels—go a long way toward a safer workplace and lower public risk.
Innovation—both incremental and disruptive—relies on having the right building blocks at hand. Work with compounds such as 4,6-diaminoresorcinol dihydrochloride often underpins advances you see in journals or emerging industrial processes. Fine-tuning a synthesis might seem trivial, but when you finally solve a tricky selectivity problem or shave hours off a multi-step process, the impact ripples through the whole research effort. For me, watching a team switch to this reagent and suddenly hit target yields or improved dye fastness highlighted how the right specialty chemical influences everything from resource use to project timelines. Reflecting on those moments, I see chemistry’s quiet champions as much more than catalog entries—they become active partners in discovery.
Chemicals like this one sit at the intersection of scientific demand and unpredictable market forces. As production methods improve—whether through green chemistry initiatives or tighter process controls—the opportunities broaden. Uptake in life sciences has led to greater scrutiny around trace impurities and batch reproducibility. Increased interest from electronics and polymer sectors also drives the search for custom derivatives or formulated blends. Companies that traditionally relied on broader commodity chemicals find themselves shopping for tailored ingredients that serve precise technical demands. Being ready means building trusted relationships with both domestic and international suppliers, constantly reviewing specifications, and staying nimble as end-use requirements change. From a buyer’s vantage point, these trends do not just drive prices—they shape which innovations reach the market and which ones stall out.
Making smart choices about specialty chemicals demands more than a quick online search. Scientists, engineers, and procurement specialists benefit from accessible, accurate information about sourcing, application, safety, and performance. Misinformation or incomplete data can derail projects and even threaten user safety. As someone who has seen both sides—buyer and user—I know how valuable credible, transparent data becomes. Reliable suppliers share not just certificates and product descriptions but real-use case studies, testimonials from end-users, and peer-reviewed citations. The best outcomes always flow from dialogue across the supply chain: chemists sharing application details, suppliers explaining formulation options, and quality teams flagging early warnings about storage or compatibility challenges.
One significant asset rarely mentioned in trade brochures is the pool of experience from colleagues, mentors, and other users. Forums, technical working groups, and professional societies all help build a shared body of knowledge. During my own projects, advice from peers solved countless small problems with formulation or troubleshooting. Newcomers benefit especially from accessible guides and lived experience—tips about proper weighing, storage, mixing protocols, and hazard management. These informal channels turn technical expertise into practical wisdom, shortening learning curves and building professional confidence.
Science and manufacturing never stand still. Wider adoption of advanced analytics—mass spectrometry, high-resolution NMR—lets chemists spot and address trace impurities that would have slipped by a decade ago. Suppliers who invest in modern quality-control infrastructure can promise and deliver higher consistency for compounds like 4,6-diaminoresorcinol dihydrochloride. As sustainability pressures mount, research into greener synthesis and alternative raw materials intensifies. Some laboratories bet on biosourced aromatics to reduce environmental impact, while others optimize existing processes to minimize energy use and hazardous byproducts. For every challenge—whether it’s regulatory change, shifting market demand, or internal resource constraint—there are practical steps forward rooted in open communication and evidence-based decision making.
A specialty chemical only seems arcane until you experience its effects on daily work. Scarce or inconsistent supply can grind research progress to a halt; reliable access unlocks new possibilities. The lessons apply beyond just one reagent: clear standards, strong supplier partnerships, robust record keeping, and a culture of information sharing. Through years at the lab bench and stints in procurement and project management, I’ve seen how much gets done when people don’t need to worry about the reliability of core materials. Products like 4,6-diaminoresorcinol dihydrochloride do more than support experiments—they form the foundation for growth in science, industry, and even safer consumer products.
Not all research or manufacturing outfits face the same priorities. Some drive for the lowest possible cost, others focus on sustainability, and still others emphasize safety above all. The balancing act requires both technical and business acumen. Whenever new projects launch, team leaders ask: Will the product source remain reliable as demand grows? How well does it integrate with changing regulatory expectations? What additional information or support might teams request from upstream partners? Thoughtful answers, not automatic reassurances or empty claims, ultimately build confidence across the supply chain.
For those seeking to get the best out of 4,6-diaminoresorcinol dihydrochloride, simple steps pay lasting dividends. Audit suppliers regularly and dig deeper than flashy marketing promises. Foster direct communication channels between users, safety officers, and procurement. Maintain up-to-date records and documentation—not only to please auditors, but to empower rapid troubleshooting and informed decision making. Encourage team members to participate in knowledge-sharing forums and training. Above all, adopt a mindset that values both the scientific detail and the broader stewardship of materials and information. This approach supports quality outcomes and drives lasting progress in every field where specialty chemicals like this play a part.