Products

2-Chloroacetamidoacetanilide

    • Product Name: 2-Chloroacetamidoacetanilide
    • Alias: N-(2-Chloroacetyl)-N-phenylglycine
    • Einecs: 211-204-3
    • 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

    473673

    Chemical Name 2-Chloroacetamidoacetanilide
    Molecular Formula C10H11ClN2O2
    Molecular Weight 226.66 g/mol
    Cas Number 127-20-8
    Appearance White to off-white solid
    Melting Point 146-150°C
    Solubility Slightly soluble in water, soluble in organic solvents
    Boiling Point Decomposes before boiling
    Structure Anilide derivative with chloroacetamido and acetanilide groups
    Purity Typically ≥98%
    Synonyms N-(2-Chloroacetyl)-N-phenylglycine amide
    Storage Conditions Store in a cool, dry, well-ventilated place

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

    Packing & Storage
    Packing Laboratory-grade 2-Chloroacetamidoacetanilide, 100g, is sealed in a white HDPE bottle with a tamper-evident cap and hazard labeling.
    Shipping 2-Chloroacetamidoacetanilide is shipped in tightly sealed containers, protected from moisture and direct sunlight. The chemical should be handled and transported according to local regulations for hazardous materials. Proper labeling, documentation, and safety precautions such as secondary containment are required to prevent leaks or accidental exposure during transit.
    Storage 2-Chloroacetamidoacetanilide should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from sources of ignition and incompatible substances such as strong oxidizing agents. Avoid exposure to moisture and direct sunlight. Proper labeling and secure storage are essential to prevent accidental spills or exposures. Always follow standard laboratory safety protocols.
    Application of 2-Chloroacetamidoacetanilide

    Applications of 2-Chloroacetamidoacetanilide in Industrial Manufacturing

    As a direct manufacturer of 2-Chloroacetamidoacetanilide, we supply this compound for critical roles in several industrial sectors. Below, we outline its main downstream uses, referencing authentic application fields, industry specifications, and processing requirements.

    1. Intermediate for Pharmaceutical Synthesis

    Pharmaceutical companies incorporate 2-Chloroacetamidoacetanilide as a building block when synthesizing specific APIs, notably within certain cephalosporin and penicillin derivative pathways. Process chemists favor this molecule in nucleophilic substitution reactions, utilizing its chloroacetamido and anilide functionality to achieve complex target molecules without excessive byproduct formation. Reaction conditions demand careful control to comply with residual solvent and impurity profiles for regulated drug intermediates. Manufacturers routinely conduct multi-step batch reactions under nitrogen, followed by chromatographic purification and strict in-process monitoring.

    Industry compliance standards

    • ICH Q7 Good Manufacturing Practice for Active Pharmaceutical Ingredients
    • USP <795> for non-sterile pharmaceutical production
    • EMA Guidelines on Genotoxic Impurities
    • EU Regulation (EC) No 1907/2006 (REACH)

    Typical usage ratio

    • 10–30% molar equivalent relative to the core substrate, with adjustment based on target yield and downstream synthetic route

    Downstream process integration

    • Enters during the formation of β-lactam rings in specialty cephalosporin intermediates
    • Utilized in amide coupling stages for penicillin derivatives
    • Often followed by fractionation and analytical HPLC for purity control
    • Enforced nitrogen blanketing during reaction to limit exposure and decomposition

    Final product types

    • Broad-spectrum cephalosporin intermediates
    • Semi-synthetic penicillin precursors
    • Custom API intermediates for contract manufacturing partners
    • Impurity reference standards for pharmaceutical QC labs

    2. Reactive Component for Specialty Dye Manufacturing

    Textile dye manufacturers depend on 2-Chloroacetamidoacetanilide to introduce stable amide and aromatic moieties into select azo and anthraquinone dye compounds. Its use during coupling reactions enables chromophore tailoring for niche fabric coloration, including heat and lightfast grades. Processing typically involves first dissolving the aromatic amide in isopropanol or DMF, followed by controlled heating and stepwise addition of diazonium salts or coupling components. Personnel must ensure complete reaction and post-process neutralization, as outlined by textile chemical safety guidelines.

    Industry compliance standards

    • OEKO-TEX® Standard 100 for harmful substance limits in textiles
    • ZDHC Manufacturing Restricted Substances List (MRSL)
    • REACH Annex XVII restrictions (aromatic amines and dye intermediates)
    • ISO 105-C06:2010 Textile Testing for dye fastness

    Typical usage ratio

    • 3–7% by weight relative to the dye total, adjusted for shade depth and desired spectral properties

    Downstream process integration

    • Charged as a primary coupling agent during azo dye synthesis
    • Added post-diazo coupling for functional group introduction in complex dye structures
    • Subjected to acid-base workup and filtration to recover final dye cakes
    • Monitored for residual amide by HPLC as per end-user dyehouse requirements

    Final product types

    • Reactive cotton dyes
    • Polyester fiber dyes
    • Printing paste concentrate for digital textile applications
    • Heatfast pigment concentrates for technical fabrics

    3. Agrochemical Synthesis Intermediate

    Producers of modern crop protection agents employ 2-Chloroacetamidoacetanilide within key synthesis steps for acetanilide-class herbicides and pre-emergent pesticides. The material’s reactivity allows efficient integration of functional aromatic and acyl groups into final actives. Processing generally uses anhydrous conditions to avoid hydrolysis, and requires in-line monitoring for unreacted intermediates to meet regulatory impurity thresholds. Scale-up involves sequential esterification and amidation reactions, sometimes under pressurized vessel conditions, followed by solvent-switch and controlled crystallization.

    Industry compliance standards

    • FAO/WHO specifications for pesticide technical grade standards
    • OECD Guidelines for the Testing of Chemicals
    • 28 CFR Part 158—EPA data requirements for pesticide registration
    • SOPs for batch traceability under ISO 9001:2015

    Typical usage ratio

    • 8–15% relative to the primary herbicidal core, modifiable by target loading and product purity constraints

    Downstream process integration

    • Utilized in the acylation or N-alkylation step of the active ingredient synthesis
    • Introduced under inert gas for chain extension or to build side-chain functionality
    • Residual solvent removal and dry-milling prior to formulation as technical concentrate
    • QC sampling for off-spec residues in final herbicide actives

    Final product types

    • Selective pre-emergence herbicide technicals (e.g. acetanilide class)
    • Agrochemical intermediate stock for downstream synthesis
    • Formulated wettable powders and dispersible granules
    • Reference impurities for agrochemical method validation

    4. Monomer for Polymeric Material Additives

    Specialty plastic and coating manufacturers rely on this compound during the synthesis of engineered copolymers and high-performance resins. Its unique aromatic and amido groups enhance polymer matrix compatibility, contributing to thermal and mechanical property control in finished films or molded articles. Standard practices involve blending the material with other monomers and initiators in controlled-ratio polymerization reactors. Integration at the pre-polymer stage allows process chemists to control polymer backbone functionality, crosslinking potential, and physical property endpoints, followed by devolatilization and pelletizing.

    Industry compliance standards

    • ISO 9001 for process and QC management in plastics manufacturing
    • FDA 21 CFR 177.1520 (if intended for certain food-contact polymers)
    • ASTM D256 for impact resistance and performance standardization
    • EN 71-3:2019 for migration of hazardous elements in plastics

    Typical usage ratio

    • 1–5% by weight of total monomer feed, optimized for desired additive concentration and target physical properties

    Downstream process integration

    • Introduced during monomer blending prior to chain initiation step
    • Dispersion under mechanical agitation at moderated temperatures
    • In-process FTIR or GPC analysis to monitor copolymerization rate
    • Post-polymerization vacuum stripping and granulation

    Final product types

    • Modified engineering thermoplastics
    • Additive masterbatches for specialty films
    • High-performance coatings for electronic components
    • Molded technical parts for the automotive industry

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    Certification & Compliance
    More Introduction

    Introducing 2-Chloroacetamidoacetanilide: A Manufacturer’s Perspective

    Proudly Made in Our Reactors

    As a chemical manufacturer with decades of practical experience, 2-Chloroacetamidoacetanilide stands out as one of those niche yet essential molecules we have steadily refined in our production halls. Whether for research, specialty intermediates, or finished active ingredients, this compound presents reliable chemistry for professionals who appreciate consistency at scale. Our own process starts with strict raw material selection — we choose only high-purity chloroacetyl chloride and the purest acetanilide. This focus isn’t just about yield numbers; it’s how we prevent byproduct formation and keep the final material within narrow impurity ranges. Each batch comes off our lines after real-time monitoring and titration checks performed by skilled operators, not just sensors and algorithms. As quickly as possible after synthesis, we act to protect the batch from moisture and atmosphere, since even small lapses hurt the product's subsequent stability and reaction profiles.

    Understanding Its Place in Synthesis

    2-Chloroacetamidoacetanilide doesn’t draw crowds like commodity chemicals, but its role in custom synthesis speaks louder. Teams in pharmaceutical and agrochemical plants still rely on compounds like this as key intermediates when building more complex structures. Whether in amide-coupling routes or as a building block for substituted anilide chemistries, it holds its own compared to other halogenated acetanilides, thanks to a careful balance of reactivity and selective transformation possibilities. Over years, feedback from researchers has shaped our own manufacturing tweaks, from fractionation improvements for purer isomer profiles to finer drying steps that reduce residual moisture — small details that save headaches at scale.

    The Right Model for Performance

    In today’s crowded fine chemicals sphere, model numbers mean less than credible output. Our 2-Chloroacetamidoacetanilide arrives with well-documented batch history and a tight melting point specification. We verify every shipment with high-performance liquid chromatography to confirm main peak purity, not just assumed “specification range.” We also go beyond typical color standards; our operators check each lot visually and by spectrophotometry for signs of discoloration or early degradation. If reprocessing is needed, we own that choice in-house — not every supplier takes that responsibility.

    Purity in Practice, Not Just on Paper

    We listen to patent chemists and process specialists who’ve told us that even subtle variations in chloride content, or trace unreacted chloroacetyl groups, can change downstream yield outcomes. Our tightening of column operation schedules helps limit those very pitfalls. During crystallization, our staff check habit and size by hand lens and microscope to avoid batch-to-batch variability. Filtration isn’t just about speed; our crews focus on removing occluded mother liquor, since sticky residues can foul the product or interfere in later steps. Years of attention to these details have paid off. By focusing on quietly reliable output, we’ve avoided frantic customer calls for replacements or explanations.

    How Users Put it to Work

    Much of the 2-Chloroacetamidoacetanilide we manufacture sees service in small quantity custom synthesis labs where precise molecular construction matters most. Researchers use it to introduce functional groups with predictable behavior, especially where slow-release or delayed activity is needed in the final molecule. Our partners have used it as a nucleophile in alkylations and as an intermediate in heterocycle formation, citing its ability to perform under different stringency conditions without byproduct formation typical of other chloroacetyl derivatives.

    Some pharmaceutical customers integrate the compound into lead diversification programs, capitalizing on its stability during workup but enough reactivity for smooth, one-pot or two-stage syntheses. That specific property — stable but not inert — came after listening to seasoned process chemists who value materials that don't rot away over storage or shift purity in transport. Others in the agchem space value its fine crystalline form for measured dosing and ease of incorporation into larger batch blends.

    Comparing Against the Competition

    We’ve watched other chloroacetanilide variants get pitched at lower prices; some seem tempting until performance tells the real story. Broadly, 2-Chloroacetamidoacetanilide stands apart from simple chloroacetanilides or multi-substituted aniline derivatives because it strikes a middle ground in reactivity, shelf life, and worker safety. Some alternatives dissolve too poorly, leading to inconsistent product distribution in subsequent processing. Others are either too reactive, risking unwanted side-reactions, or too sluggish to react in reasonable cycles. We test samples on our own benches, taking care to monitor exotherms, hydrolysis, and crystallization times. Results consistently confirm that batches made through our established route yield fewer impurities and exhibit less batch aging than what we've seen from shortcut or low-cost processes.

    Granular observations drive our process improvements. For one, we've invested in better jacketed vessels that manage heat flow with more precision, avoiding local overheating — which can drive impurity formation, something off-brand suppliers tend to ignore. Reactor operators track pH and conductivity readings throughout addition and workup, helping to amaze repeat customers who come back simply because our batches behave as expected from flask to drum.

    Physical and Chemical Characteristics in Real-World Settings

    While it’s easy for a datasheet to note melting range and solubility, these numbers sometimes miss critical context. Our technical team prefers to measure not just melting, but decomposition onset, which matters to formulation experts working at higher temperatures. The white to light tan crystalline form, which we maintain via temperature-controlled storage rooms, ensures the product packs and dispenses without dusting or caking — a key feature for automated feeder lines in larger pilot operations. Lower-cost versions arriving from other markets might display a grey or off-color cast, pointing to trace organic residues. These can trip up highly sensitive downstream routes or expose operators to unknown contaminants.

    Over time, we observed that maintaining narrow particle size and avoiding micro-aggregation gives not only reproducible analytical values but also lends an operational advantage in continuous feeding situations. Our mills and sifting equipment catch oversized or undersized fractions, reducing the likelihood of transfer losses or inconsistent batch reactivity. We monitor not just inventory, but stability with regular retests, seeing firsthand that batches packed with vigilant exclusion of air and moisture routinely outlast standard shelf expectations.

    Meeting Food, Pharma, and Specialty Chemical Demands

    Unlike broad-application bulk chemicals, 2-Chloroacetamidoacetanilide fits into specialized portfolios. The raw material traceability we maintain supports both clinical trial supply teams and scale-up managers seeking to document every detail for regulatory submissions. Plant leaders from excipient producers and small-molecule innovators alike request detailed impurity profiles, which we generate and disclose based on actual instrument output, not round-number estimates.

    We keep eyes on regulatory compliance for restricted impurities or heavy metals that can sneak into nonchalant production chains. Our lab checks by ICP-MS and GC regularly verify the absence of extraneous elements like mercury or residual solvents. Because we've walked lines ourselves, we understand that one-off contaminations can trigger all manner of delays, so the risk-averse among our clients have learned they can trust our material for use in both pharmaceutical intermediate assembly and food-contact research.

    On-Site Insight: The Value of In-House Knowledge

    Some buyers complain about lengthy certificate of analysis templates that fail to reflect day-to-day variability. Operators on our floor, with collective decades handling not just this product but its kin, contribute real-world corrections to laboratory reporting. If a slight color drift or a whiff of off-odor appears, upstream staff retrace the production run until source factors get resolved. We value the hands-on knowledge that prevents specification drift, not just what goes into printouts. Years dealing with temperature swings, pump failures, and raw input substitutions reinforce the value of maintaining our process narrative with living, not static, documentation.

    Supporting Technical Questions with Real Answers

    Researchers new to halogenated anilides often ask for hands-on feedback about side reactions, hydrolysis rates, or operational temperatures. We’ve hosted dozens of process pilots where we adjust variables on the shop floor. These practice runs, not just literature reviews, give clients confidence when transferring recipes into their own environments. Stories abound of clients receiving low-quality materials from traders, only to face dissolved impurities or mismatched melting points down the line. Those lessons from the field push us to over-communicate, providing full analytical suites and, by request, extra material for validation runs.

    Questions about shelf life, compatibility with different solvents, or cleaning protocols come to us directly from users — not just purchasing agents. We answer from our logs, pointing out, for example, which grades handle better in DMSO compared to acetonitrile, or what air exposure times still preserve functional group performance. Partnership, in our experience, rests on knowing precisely what’s in the drum before it ships, which beats surprises after delivery every time.

    Product Improvements Driven by Experience

    Many years ago, our batches showed slight moisture pickup during monsoon seasons, causing headaches in scale-up. That weakness led us to install new climate controls and humidity alarms throughout our packing lines. Since making those changes, field failures related to hydrolysis fell below measurable levels. The lesson came from years of loading, unloading, and re-testing, not from theory.

    On more than one occasion, our technical director shadowed project teams on the customer’s own site, watching how our product performed under stress. Feedback from that direct involvement revealed subtle tweaks to our process that improved filtering and reduced recommissioning cycles. A sharp learning took place from a project where late-acting contaminants traced back to recycled container liners. That prompted us to develop sealed liner shipments and work with supply chain partners to keep the drum environment close to inert from fill to open.

    Why Choose a Proven Line Rather Than an Unknown Supply

    With 2-Chloroacetamidoacetanilide, the true difference emerges not in slide decks, but in the lived results of actual projects. Regular customers who rely on predictable reactivity and sharply defined analytical profiles say they value less downtime and fewer “troubleshooting” investigations. We keep our specification windows tight not just for regulatory reasons, but to make scale transfers more reliable for users. Time has taught us that quality lapses at this intermediate stage ripple up in lost product, unplanned maintenance, or extra purification steps.

    We encourage laboratories and production engineers to work with us directly, avoiding the maze of intermediaries, since process understanding gets sharper the closer users come to our actual synthesis crews. Whether tackling a literature route or a proprietary compound, having a source focused on batch-by-batch real-world performance eliminates guesswork.

    Solutions for Efficiency and Cost

    Production scale comes with its own complexity, far beyond what small lots face. Over years, we’ve learned that the efficiency of 2-Chloroacetamidoacetanilide use in higher volume reactors depends on not only purity but on how the batch behaves in dissolution, transfer, and recovery. We selected packaging designed to speed access in automated settings, with fewer seals and lighter liners to cut labor steps. That sort of improvement matters both for small- to mid-size operations and for larger users managing hundreds of kilograms per month.

    Addressing cost isn’t about cutting corners but eliminating hidden waste — be it from excessive handling, unnecessary rework, or unpredictable off-spec rejections. Our internal cost reductions came less from negotiating raw material prices and more from process analytics. By recording every temperature, pH, and yield for thousands of runs, our teams have implemented meaningful tweaks such as minor dwell time modifications or solvent ratio changes that raise consistency and lower reprocessing. These efforts free customers from surprises tied to batch variability or post-delivery troubleshooting.

    Looking Ahead: Building Trust Through Transparency

    We remain convinced that a manufacturer’s responsibility lies in more than filling a drum with white crystalline solid. The ongoing demand for 2-Chloroacetamidoacetanilide in bespoke synthesis, traceable intermediates, and proven formulations flows from a simple principle: customers need results, not just certificates. By opening our production floor to auditors and voicing detailed analytics, we aim for customers to judge performance through actual usage rather than only document review.

    Modern production means balancing cost, availability, and regulatory compliance without silent corners. It means having staff ready to answer detailed questions, whether those relate to process safety, impurity carryover, or shelf-life performance after six months in warehousing. For us, this involves more than technical compliance — it comes from real-world engagement, learning through direct customer feedback, and making incremental improvements batch by batch.

    2-Chloroacetamidoacetanilide rarely finds a lead role in headlines. Nonetheless, its behind-the-scenes contributions remain vital to the progress of pharmaceutical research, regulatory-compliant manufacturing, and creative synthesis. From these years around reactors, storage racks, and shipping bays, we see the real value in doing each step with care — and we continue to deliver that value for every customer who trusts us for their next project.

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