Products

O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide

    • Product Name: O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide
    • Alias: Amitraz
    • Einecs: 259-987-5
    • 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

    447393

    Chemical Name O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide
    Molecular Formula C14H13Cl2N2OPS
    Molecular Weight 375.21 g/mol
    Cas Number 2759-89-9
    Appearance White to off-white crystalline solid
    Melting Point 120-123°C
    Solubility Slightly soluble in water, soluble in organic solvents
    Boiling Point Decomposes before boiling
    Density 1.45 g/cm³ (approximate)
    Synonyms Chlorphoxim; O,O-Bis(4-chlorophenyl) N-(1-iminoethyl) thiophosphoramide
    Storage Conditions Store in a cool, dry, well-ventilated place, away from incompatible substances
    Usage Primarily used as an insecticide

    As an accredited O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.

    Packing & Storage
    Packing The chemical is packaged in a 100-gram amber glass bottle with tamper-evident seal, labeled with full chemical name and hazard information.
    Shipping **Shipping Description:** O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide should be shipped in sealed, labeled containers with secondary containment. Ship at ambient temperature unless otherwise specified, and in compliance with relevant chemical and hazardous materials regulations. Handle as a toxic substance. Include appropriate documentation and emergency contact information with shipment.
    Storage O,O-Bis(4-Chlorophenyl) N-(1-imino)ethyl thiophosphoramide should be stored in a cool, dry, and well-ventilated area, away from incompatible substances such as strong oxidizers and acids. Keep the container tightly closed and protected from moisture and direct sunlight. Store in a clearly labeled, chemical-resistant container, and follow all relevant safety protocols for toxic and potentially hazardous chemicals.
    Application of O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide

    Applications of O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide in Industrial Manufacturing

    As a dedicated manufacturer of O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide, we provide this compound directly to multiple, well-defined downstream sectors that demand consistent quality and reliable integration into advanced industrial processes. Our focus extends across several key application areas, ensuring that specification, regulatory compliance, and technical requirements are all continuously met.

    1. Agricultural Crop Protection Formulations

    Key agrochemical producers incorporate this thiophosphoramide derivative primarily in the synthesis of selective organophosphorus pesticides. Compound use requires close adherence to active ingredient regulations for different geographies. In advanced pesticide formulations, it interacts with secondary actives during pre-emulsification or suspension concentrate blending, directly affecting the stability and controlled-release properties of the final crop protection agents which are tailored for specific pest spectrums and environmental persistence.

    Industry compliance standards

    • FAO/WHO Joint Meeting on Pesticide Specifications (JMPS)
    • EPA 40 CFR Part 180: Tolerances and Exemptions for Pesticide Chemical Residues
    • EU Regulation (EC) No 1107/2009 for Plant Protection Products
    • China GB 2763 National Food Safety Standard for Maximum Residue Limits

    Typical usage ratio

    • 0.5–5% by weight as an active constituent; formulation ratios depend on required lethal dose (LD50), application method, and target pest type.

    Downstream process integration

    • Added during concentrate blending or microencapsulation. Controlled-temperature mixing and surfactant selection essential for emulsifiable concentrate stability.

    Final product types

    • Pesticide technical concentrates
    • Wettable powders
    • Suspension concentrates
    • Seed treatment agents

    2. Industrial Wood Preservation Treatments

    Timber protection manufacturers utilize this raw material to improve resistance of outdoor and in-ground use wood products against fungal decay and insect attack. The compound integrates as a primary component of organophosphorus wood preservative formulations, designed for pressure impregnation processes that allow deep substrate penetration and minimal leaching into the environment, particularly where regulatory limitation exists for persistent halogenated chemicals.

    Industry compliance standards

    • EN 599-1: Performance of Preventive Wood Preservatives
    • AWPA P8/P9: American Wood Protection Association Standards for Oil-borne and Water-borne Preservatives
    • Reach Regulation (EC) No 1907/2006 – Chemical Safety
    • OSHA Hazard Communication Standard (29 CFR 1910.1200)

    Typical usage ratio

    • Typically 2–10% by weight in preservative concentrate; dilution and uptake adjust per wood species, target retention rate (kg/m³), and project requirements.

    Downstream process integration

    • Feeds into autoclave impregnation solution. Vacuum-pressure cycles ensure substance diffusion into wood structure. Subsequent curing required before surface finishing.

    Final product types

    • Outdoor construction timber
    • Railroad ties
    • Utility poles
    • Decking and garden timbers

    3. Synthesis of Specialty Flame Retardants

    Chemical manufacturers source our thiophosphoramide compound for the preparation of custom halogen-phosphorus based flame retardants for engineering plastics and fiber applications. The molecule’s unique architecture enables covalent bonding or additive blending into thermoplastic and thermosetting resin matrices, delivering both flame inhibition and mechanical stability enhancements, especially where end-users require non-migrating flame retardant properties.

    Industry compliance standards

    • UL 94 Flammability Standard
    • RoHS Directive 2011/65/EU—Restriction of Hazardous Substances
    • REACH Annex XVII (Limits on Specific Flame Retardants)
    • ISO 4589: Oxygen Index Testing

    Typical usage ratio

    • 3–12% by mass in polymeric formulation; dosage tailored by substrate compatibility, target LOI (limiting oxygen index), and compliance with finished-product fire rating.

    Downstream process integration

    • Introduced during resin compounding or as masterbatch addition before extrusion or molding. Shear dispersion and temperature profile regulated for full reaction or mix homogeneity.

    Final product types

    • Electrical enclosures
    • Automotive interior modules
    • Flame-retardant textile fibers
    • Wire and cable insulation

    4. Intermediates for Pharmaceutical Synthesis

    Advanced pharmaceutical intermediate producers employ this compound as a building block for organophosphorus structures in selected APIs. It participates in controlled condensation or substitution reactions under GMP conditions, where precision in reactant purity and residual solvent monitoring are critical to meet downstream route-specific impurity thresholds. Product application remains confined to non-final drug substance or as a reagent for chemical transformation in targeted synthesis projects.

    Industry compliance standards

    • ICH Q7 Good Manufacturing Practice for Active Pharmaceutical Ingredients
    • US Pharmacopeia (USP) General Chapters on Residual Solvents and Impurities
    • EU GMP Part II (APIs)
    • ISO 9001:2015 Quality Management Systems

    Typical usage ratio

    • 0.1–1.5 molar equivalents relative to core reactant; adjusted per synthetic stage throughput and intermediate yield efficiency objectives.

    Downstream process integration

    • Charged at discrete reaction step in multi-stage batch synthesis. In-line QC via HPLC or NMR for consumption confirmation and monitoring of process-related impurities.

    Final product types

    • Pharmaceutical intermediates
    • Custom fine chemicals for NCE (New Chemical Entity) synthesis projects
    • Precursor compounds for medicinal chemistry research
    • Non-GMP pilot-scale R&D products

    Free Quote

    Competitive O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide prices that fit your budget—flexible terms and customized quotes for every order.

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    Certification & Compliance
    More Introduction

    O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide: Manufacturer’s Perspective on a Specialized Chemical

    What O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide Means to Us as the Producer

    We have been working directly with O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide for years in our chemical plant so we can share more than just numbers and charts. This isn’t simply another compound in the catalog or a batch code. It takes precise accuracy through every production step. We have spent much of our R&D capital learning how to synthesize and purify this molecule to serve industrial purposes. The hands-on experience with its unique characteristics shapes our insights, from handling the raw materials all the way through to shipping out the finished product.

    Product Understanding from Daily Manufacturing

    Working with this compound, we see its off-white to yellow-brown crystalline appearance emerge after a series of delicate chemical manipulations. The material demands a controlled environment—a dry atmosphere with tight temperature regulation during synthesis—since it reacts unfavorably if these conditions drift. One minor deviation can spell trouble for the whole batch. We oversee the process with real people at the reactors, watching as each phase finishes, checking color and clarity, not just ticking boxes on a procedure sheet. Years of in-plant troubleshooting have made operators skilled at noticing subtle shifts in texture or hue that warn of possible impurities or issues.

    We handle the synthesis of O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide through controlled, multi-step reactions. The process starts with carefully selected starting materials, paying strict attention to their purity. Safeguarding these inputs against trace contaminants is essential. The synthesis follows a route involving chlorophenyl reagents, proper reagents for the iminothiophosphoramide formation, and precise catalyst management. Even small errors in measuring or order of addition result in failed yields, or even completely different undesired byproducts. The reactions emit strong odors and can exotherm rapidly, so our plant’s ventilation and temperature control systems bear a heavy workload. By tuning flow rates and addition times according to operator feedback and sensor data, the process is stabilized for optimal output.

    Our staff finishes the product through a filtration and purification sequence that relies on continuous in-process checks. Before packaging, the compound faces a panel of analytical tests—IR spectroscopy, NMR, chromatography—to guarantee the absence of secondary amines or residual solvents. Nothing ships without passing these rigorous checkpoints. Our manufacturing know-how comes from real trials, mistakes, corrections, and constant data collection, so consistency is not an accident in our plant.

    Model and Specifications Developed from Real-World Demands

    Our usual production model focuses on technical-grade material with high assay and low moisture content. Through working with customers’ QA teams, we have learned most applications, including synthesis and lab-scale research, cannot tolerate high levels of specific impurities. This led our quality system to include threshold limits for elemental phosphorus residues, chloride, and specific isomers. Based on lab findings, our standard material is typically delivered with purity no less than 98%, moisture below 0.2%, and controlled particle size for proper dissolving and weighing.

    We do not use vague terms like “meets industry norms”—we work off specific QC sheets tailored by real experience. Every drum or bag leaving our plant is labeled with the production lot, assay results from that very batch, and the analyses conducted. Customers can match our delivery not only to a CAS number, but to a clear line-up of data. Any issues are handled by our technical staff, many of whom operate the very reactors and know what went into that product from start to finish.

    Typical Usage Informed by Real Practice

    Based on years of dialogue with formulation chemists and industrial users, we have found most requests for O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide come from sectors focused on intermediates for advanced organophosphorus chemistry. Customers often use this compound as a reagent for developing analogs, particularly in agricultural and pharmaceutical research where unique reactivity patterns are sought after. Reliable material purity matters—trace impurities can shut down an entire synthesis path or distort research data. Our direct contact with end-users has taught us the importance of minimizing critical side products, ensuring predictable performance during downstream applications.

    Handling tips have emerged through years of practical troubleshooting. For example, direct exposure to moisture results in gradual hydrolysis, so customers commonly request moisture-barrier packaging. We have worked closely with their teams to advise on inert gas flushing and double-layer containment. The compound’s odor can linger, so our facility adopted improved sealed packaging years ago, based on real-world storage trials in various climates. Rather than guessing at “likely” storage issues, we gather data directly from customers’ feedback rounds, then adjust our handling and shipping accordingly, making sure the material remains uncompromised from loading dock to end-user lab.

    How This Compound Differs from Related Chemicals (Grounded in Manufacturing Facts)

    Decades in organophosphorus chemistry have exposed us to a broad array of thiophosphoramides and related compounds. O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide stands out due to the position and nature of its 4-chlorophenyl substituents, which give it tailored reactivity compared to bulkier or lighter analogs. Several organophosphorus compounds with similar scaffolds show markedly different reaction profiles under identical conditions. Through side-by-side synthetic experiments in our R&D bay, we have demonstrated that even minor variations in substituent position—such as shifting a chlorine from the para to the ortho spot—cause dramatic changes downstream. These differences often translate into real operational headaches or, conversely, fresh opportunities for chemists working on novel pesticide or pharmaceutical agents.

    Unlike simpler thiophosphoramides, O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide resists hydrolysis longer in neutral settings, which buyers frequently confirm through their own bench-scale tests. Our own accelerated aging studies have shown improved shelf life for this model, provided the original container remains sealed and away from high humidity. We also see less caking and fewer issues during powder handling with this structure than with mono-phenyl or mixed-substitution analogs, which tend to absorb atmospheric moisture more quickly and clump up, especially in humid environments.

    Manufacturing this specific compound imposes stricter intermediate purification steps since the 4-chlorophenyl groups, while providing functional benefits, also foster formation of certain side products if not watched carefully. In contrast, related trisphosphoramides sometimes tolerate a more forgiving purification window but end up less stable or harder to re-dissolve in downstream processes. These differences matter in real plant life: a difficult-to-filter byproduct can slow down a whole line for hours or days, so we have optimized our cleaning and crystallization routines to deliver consistently pure product with manageable solid properties.

    Industry Insights Based on Real-World Interactions

    We keep a close pulse on market trends by exchanging technical information straight with research directors, production managers, and procurement leads who use our compound in their processes. Researchers share their project bottlenecks, whether caused by batch-to-batch inconsistency or impurity issues. That information circles back into our plant—supporting investments in better analytical equipment or tighter synthesis control. One example that stands out: years ago, one of our customers reported problems with unexpected reactivity during scale-up. After a deep technical session, we set up parallel pilot runs, ultimately revealing that traces of a byproduct unique to an older version of our process could interfere with their downstream catalyst. This direct feedback loop drove a process redesign at our facility, reducing the problematic impurity and increasing both customer yield and our reputation for reliability.

    We also see evolving regulations and stricter end-user documentation requirements each year. Hazard documentation and REACH registration have become more demanding. Our compliance team works hand-in-hand with production and QA because regulatory issues in this space do not live in paperwork—they begin and end inside real drums and bags. Each regulatory change prompts updates not only in our labeling, but also in how we store, monitor, and ship product batches. We have added batch-level traceability and adopted digital documentation so end-users can prove regulatory compliance with specific loads, not just “average” batches across months.

    Challenges, Solutions, and Lessons Learned Over Time

    Chemical manufacturing seldom presents a smooth ride, and producing O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide is no exception. Problems crop up throughout the chain—raw material shortages, moisture ingress, equipment downtime, or changes in environmental regulation. We do not view challenges as excuses. Our plant team, from line operators to process chemists, treats these obstacles as stimuli to push development forward.

    Corrosive vapors during production tested the resilience of process lines. Swapping out older gaskets and introducing more robust, chemical-resistant fittings prevented leaks and reduced maintenance delays. These capital changes born from hard-earned experience now pay for themselves many times over in lost time saved and improved safety. Handling and downstream packing also required new protocols since the compound, left exposed, attracts moisture in ways many less-chlorinated analogs do not. Continuous consultations with users led to tighter fill stations, accelerated sampling routines, and an ongoing investment in air- and moisture-barrier packaging.

    Unexpected regulatory changes—odds are we see these almost yearly—demand flexibility. Our plant integrates input from outside regulatory bodies promptly by running expedited hazard reviews, then executes technical changes, whether that means managing new watchlists for trace contaminants, updating lab practices to prevent cross-contamination, or investing in analytical detection for even faint impurities requiring new detection methods. Instead of treating compliance as a once-yearly headache, we have woven it into regular production. This sort of real-time adaptation ensures customers face fewer regulatory headaches themselves and fosters long-term partnerships based on problem-solving, not blame-shifting.

    Product Stewardship and Customer Partnership in the Real World

    Being a direct manufacturer does not mean our relationship with O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide—and its customers—ends at the shipping dock. We field plenty of technical questions, usually from teams engaged in high-precision synthesis or process development who need more than just paperwork assurance about the consistency or origin of specific lots. If a customer’s pilot production fails, we look for root causes side-by-side, pulling our plant’s historical run data, running fresh lab tests on retained samples, and even synthesizing small-scale verification runs if needed. Our approach stays hands-on, never relying solely on theoretical modeling when practical insight remains the best teacher.

    We are frank with customers about potential limitations in the chemistry or physical handling procedures for this compound. Clean feedback channels and open documentation pave the way for customizations or modifications upon request. Occasionally, a research partner asks for a narrower particle range or a tweak in the drying conditions. Instead of quoting a manual, we engage our R&D and plant teams so adjustments reflect not just what’s possible, but what is consistently reproducible at scale. This mindset rewards both sides: the end-user receives a product dialed in for their process, and we gain valuable technical knowledge to feed back into routine production.

    Building Reliability Through Practical Experience

    It is easy for outside observers to picture chemical production as an endless repetition of the same batch over and over. In reality, we face constant variability in raw material supply, plant conditions, and application demands. Consistency—the kind that matters to high-end users—comes from knowledgeable staff, grounded process controls, and open technical collaboration. Introducing new sourcing or switching reagent lots is never done blindly: each tweak sparks discussion between QA, plant managers, and chemists before ever running a scaled batch. Our regular plant audits, technical workshops for operators, and investments in staff training are grounded in the daily intention to catch errors early, correct them, and share learning up and down the line.

    Many of us have worked decades in this plant, carried out countless batches, and watched failures as well as improvements unfold in real time. This foundation fortifies the reliability and peace of mind we deliver to end users. It reminds us that O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide, like any advanced chemical, depends on the hands and eyes of real people who respect its quirks and potential.

    Outlook for Future Development

    As new downstream applications for O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide appear in published research, we continually adapt. The growing need for cleaner, more controlled chemical intermediates in pharmaceuticals, crop protection, and materials science keeps us focused on both technical advancement and flexible manufacturing. Real-world feedback from adopters has prompted us to invest further in detection methods for trace-level impurities, upgrade our logistics for global consistency, and remain responsive should customers present new specification requests. Staying nimble, grounded, and collaborative, we expect our future work to support stronger, safer, and more innovative outcomes for everyone depending on advanced chemical intermediates.

    Working as a manufacturer of O,O-Bis(4-Chlorophenyl) N-(1-Imino)Ethyl Thiophosphoramide means dealing with the tangible, daily reality of complex chemistry. Through learning alongside users and continually upgrading our own standards, we champion both reliability and innovation—serving those who rely on this compound in their most demanding work.

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