Tengfei Creation Center,55 Jiangjun Avenue, Jiangning District,Nanjing admin@sinochem-nanjing.com 3389378665@qq.com
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2-Anthramine

    • Product Name 2-Anthramine
    • Alias 2-Aminoantracene
    • Einecs 205-572-7
    • 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

    576956

    Iupac Name anthracen-2-amine
    Cas Number 613-13-8
    Molecular Formula C14H11N
    Molar Mass 193.247 g/mol
    Appearance yellowish or brownish solid
    Melting Point 120-122 °C
    Boiling Point 390 °C
    Density 1.18 g/cm³
    Solubility In Water insoluble
    Pubchem Cid 6768

    As an accredited 2-Anthramine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.

    Packing & Storage
    Packing The 2-Anthramine is supplied in a sealed, amber glass bottle containing 25 grams, labeled with hazard warnings and handling instructions.
    Shipping 2-Anthramine should be shipped in tightly sealed containers, protected from light, moisture, and incompatible substances. It must be clearly labeled as hazardous and comply with local and international transport regulations. Appropriate safety documentation (SDS) should accompany the shipment, and handlers must wear proper personal protective equipment due to its toxic nature.
    Storage 2-Anthramine 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 acids. Protect it from light and moisture. Store it in a chemical fume hood if possible, and clearly label the container. Follow all relevant legal and safety guidelines for hazardous organic amines.
    Free Quote

    Competitive 2-Anthramine prices that fit your budget—flexible terms and customized quotes for every order.

    For samples, pricing, or more information, please call us at +8615371019725 or mail to admin@sinochem-nanjing.com.

    We will respond to you as soon as possible.

    Tel: +8615371019725

    Email: admin@sinochem-nanjing.com

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    Certification & Compliance
    More Introduction

    Introducing 2-Anthramine: Our Perspective as the Manufacturer

    The Chemical and Its Role in Industry

    2-Anthramine carries significance in industrial chemistry, serving mainly as a vital intermediate in advanced dye and pigment synthesis. In our facility, real manufacturing processes shape its crystalline form and purity in ways traders and resellers rarely see up close. Each batch, assigned the model 2AM-098 for tracking within our quality system, goes through precise controls to ensure it meets rigorous standards. We have walked the floor during every scale-up, testing new synthesis routes, and tweaking purification—each adjustment informed by raw data from our own reactors. A lab can write out a hundred data sheets, but behind every published assay, countless hours stand between pilot results and the clean, high-quality powder we finally ship out.

    The usual output from our reactors is a pale yellow solid, melting near 114°C, and its purity usually exceeds the 99.5% mark on GC and HPLC analyses run on site. This is not just a number for paperwork; every few tenths of a percent can mean the difference between a clean final dye and a product streaked with unwanted residue. We've handled other anthracene derivatives on our lines—2-Anthramine, or o-aminoanthracene, distinguishes itself for applications demanding real thermal stability and clean, predictable reactivity.

    Direct Experience in Formulation and Handling

    Manufacturing workers at our plant describe 2-Anthramine’s powder as dense and free-flowing, which matters to those downstream who mix it into reaction vessels. We designed our storage systems after discovering during an especially humid season that absorption of moisture leads to caking, a hazard both for flow and reactivity. On the production line, small changes in particle size distribution impact filtering times and batch consistency, so we continually monitor and adjust micronization, and we reject any batch where particles aggregate outside specification. No online spec sheet addresses such process headaches; these problems and their solutions come only from years of direct handling.

    We work with batch sizes that can fill drums by the pallet, not mere flasks. Environmental controls feature acid-resistant linings and constant local monitoring for airborne particulates, after a handful of cases in the 1990s showed routine handling could mean exposure risks. We recalibrated not just what scale means in terms of output, but how safe handling shapes day-to-day decisions. Feedback from technical customers and our own operators makes clear that certainty in batch reproducibility always matters more than a theoretical purity higher by a tenth of a percent.

    Purity, Consistency, and Their Impact Downstream

    In dyes and pigments, purity defines performance. Our facility has committed, year upon year, to stricter monitoring and lot tracking. Take a typical downstream process: triazine dye synthesis, where even trace contaminants from upstream 2-Anthramine can introduce unpredictable undertones to fabric finishes. We have received plenty of puzzled phone calls from customers before we invested in high-end HPLC and NMR suites, and since then, consistent analysis guards both us and our partners against variability. Technical teams now rely on pre-shipment COAs that reflect direct runs from our latest lots. These may read like sterile paperwork, but each represents a handshake, a trust that what is ordered is truly delivered.

    Responsible Sourcing and Sustainability

    Coming from the actual shop floor, sourcing raw anthracene for 2-Anthramine demands reliable partners in both petrochemical and coal-tar streams. We vet and audit these upstream suppliers in person. A few years ago, a gap in supply integrity forced us to revalidate our own suppliers, and we chose to walk away from a few who did not match our documentation standards. Beyond just legal compliance, this decision stemmed from cases where poorly tracked feedstocks led to product recalls—not just costly, but undermining faith with end-users. Our QC data shows tighter traceability has reduced batch-to-batch variation, and customers downstream see fewer surprises.

    On-site, we manage waste streams arising from nitration and reduction steps with both incineration and specialized separation. Our investment in closed-loop handling for solvents like DMF or acetic acid means both safer working conditions and reduced annual VOC emissions. Local regulators often tour our waste management lines; they have flagged improvements, but also respect that commitment to sustainable practice starts by reengineering, not just reporting. It matters for us because our own employees live in nearby communities—the line between plant and home is not so distant from the human perspective.

    Comparison with Other Aminoanthracenes

    Chemists approach anthracene derivatives as a family—options like 1-aminoanthracene, 9-aminoanthracene, and 2-Anthramine may seem interchangeable in broad tables. In practice, real-world synthesis exposes their differences. In our pilot facility, substituent position controls both solubility and reactivity. For example, 9-aminoanthracene’s amine sits at the central position, giving it higher nucleophilicity but lower stability against light and heat. 2-Anthramine behaves less aggressively, offering controlled coupling and reliable outcomes during diazotization or electrophilic substitutions. End-users in dye synthesis, or those working with functional materials, find these subtleties define whether a project succeeds or fails. Ours is not a warehouse mixing up the catalog; bench experience defines our technical recommendations.

    In practical terms, 2-Anthramine grants unique spectral characteristics after coupling. For example, when combined to produce vat dyes or solvent-extracted pigments, shifts in color expression and fastness reflect its substitution pattern. Academic data may propose equivalence between derivatives, yet ongoing long-term studies in customer feedback cycles prove otherwise. After hundreds of tons produced and tracked, we see which runs result in robust, lasting shades and which fade under industrial lighting or harsh washing. Insights like these rarely survive product brochures written far from the production floor.

    Technical Experience With Applications

    Most demand for 2-Anthramine arises from two sectors: dye intermediates and organic synthesis for specialty chemicals. Our plant’s history involves constant iteration between these uses. Some partners push synthesis toward high-performance pigments like anthraquinone derivatives; others develop advanced polymers or fluorescent agents, leveraging its aromatic core. Countless R&D attempts have failed on paper, but by adjusting process pressures, catalyst additions, and purification steps based on operator feedback, we've salvaged projects marked unsolvable.

    In dye applications, the difference between a successful run and a failed one often boils down to the presence of minute by-products in the anthramine source. Only repetitive batch analysis and open lines of communication between production and lab staff have enabled us to tighten those margins. We see high-performing textile dyes emerge consistently only because the underlying intermediate maintains both purity and defined physical characteristics, like particle fineness and dispersibility, not always reported outside a manufacturing context.

    Our experience with polymers and functional materials repeats these lessons. 2-Anthramine grants aromaticity and electron-rich substitution needed for conductive polymer frameworks and advanced cross-linking agents. We have adjusted our own synthetic lines in direct response to partners developing new electronics or light-absorbing materials. Customers reveal early research needs, and we in turn adjust production—agility forged by direct, hands-on involvement rather than secondhand reports.

    Quality Assurance and Regulatory Context

    Quality assurance forms not just a checklist, but an operating philosophy built from manufacturing practice. Our QC managers insist on trend analysis for key process indicators: melt point, moisture, particle profile. We watched new analytical techniques, such as LC-MS, prove in-house that some minor by-products elude detection by more traditional GC scans. Our investment in deeper analytical capacity stems from learning, sometimes the hard way, that unchecked trace contaminants can halt downstream production lines, potentially causing economic losses across industrial alliances.

    The working relationship between regulatory bodies and our technical departments grew out of practical need. As a classified hazardous substance, 2-Anthramine presents both handling and environmental liabilities. Years of experience navigating local, national, and international regulation built our current documentation and compliance strategies. Our team brings regulatory changes straight to the plant floor: operators update their procedures for new exposure limits, shift managers retrain staff after any incident, and environmental leads maintain up-to-date licensing for storage and disposal. Few outside the plant appreciate the hours behind each safe shipment, or how a single spilled drum can mean days of reports and retraining.

    End-User Support and Collaboration

    Our involvement as manufacturers does not end at delivery. Over time, collaborations between our technical team and end-users have led to product improvements beyond what spec sheets advise. Users often ask why 2-Anthramine from different sources behaves unpredictably, even when technical data looks the same. We share findings directly: effects of differing impurity profiles, handling moisture, or how variance in milling leads to application-specific outcomes. Experiences such as troubleshooting a failed synthesis run in a pigment plant led to joint investigations, adjustments on both our and the downstream customer’s procedure, and mutual learning.

    We encourage regular feedback, not just transactional updates. Technical representatives from downstream companies visit our site, observe actual batches under production, and test samples on the spot. Our own process chemists have gone on-site to customer plants, working shoulder to shoulder to resolve a fouled batch or unexpected physical property. These relationships foster advancements in how 2-Anthramine performs both in lab-scale pilots and industrial-scale implementation. Rather than distant, theoretical use, most solutions emerge from hands-on collaboration and dialogue, grounded in the grit of real production work.

    Challenges in Manufacturing and Opportunities for Improvement

    Making 2-Anthramine presents real-world difficulties, from managing exothermic reactions in the nitration stage to minimizing by-product formation during the reduction. We have faced abrupt shutdowns, process controller failures, and even lost raw material loads. In response, our maintenance team implemented daily checks after an incident resulted in off-grade material that risked shipment rejection. Equipment failures, often invisible outside the production chain, quickly underline the need for robust preventive procedures.

    Another enduring challenge lies in balancing growing demand with consistently tight specification. As international standards evolve, allowable impurity profiles narrow; customers push for fewer trace contaminants and ever more detailed certificates of analysis. In response, we have upgraded instrumentation, retrained staff, and established a real-time production dashboard visible from any office in the plant. These changes stem from the pressure of firsthand experience: manufacturers carry responsibility not just for one product, but for the chain of projects, innovation, and livelihoods that depend on reliable supply and safe manufacturing.

    Continual improvement remains a founding value. We regularly review incident logs, encourage operator suggestions, and invest a significant share of margins into both incremental and breakthrough upgrades. Recent studies in our lab aim at greener synthetic routes, with hopes of both reducing environmental impact and improving overall process economics. Direct conversation and feedback with downstream users also open entirely new directions—unanticipated needs sometimes foster the most valuable innovation.

    Why Direct Manufacturing Matters

    As direct manufacturers, we see the full picture of 2-Anthramine, from sourcing and synthesis to delivery and final application. Each step introduces uncontrollable variables, yet long-standing experience, feedback loops, and willingness to invest in both people and equipment push quality ever higher. Factories like ours face real consequences for every decision, winning trust batch after batch by proving reliability in ways third-party sellers or casual traders cannot duplicate. Our commentary reflects lived realities, technical insight forged by years standing between raw material and finished product. The success of 2-Anthramine, and the communities and companies it supports, stems from this lineage of practical experience and honest conversation.