|
HS Code |
443577 |
| Productname | 2,6-Dichloro-3-Fluoro Acetophenone |
| Casnumber | 42516-34-3 |
| Molecularformula | C8H5Cl2FO |
| Molecularweight | 207.03 |
| Appearance | White to off-white solid |
| Meltingpoint | 61-65°C |
| Purity | Typically ≥98% |
| Solubility | Slightly soluble in organic solvents |
| Smiles | CC(=O)C1=C(C(=C(C=C1)Cl)F)Cl |
| Inchikey | TWZQTIXBSYAPMR-UHFFFAOYSA-N |
| Synonyms | 1-(2,6-Dichloro-3-fluorophenyl)ethanone |
| Storageconditions | Store in a cool, dry place and keep container tightly closed |
As an accredited 2,6-Dichloro-3-Fluoro Acetophenone factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
|
Purity 98%: 2,6-Dichloro-3-Fluoro Acetophenone with a purity of 98% is used in pharmaceutical intermediate synthesis, where it ensures high reaction yield and product consistency. Melting Point 68°C: 2,6-Dichloro-3-Fluoro Acetophenone with a melting point of 68°C is used in agrochemical formulation, where it promotes uniform solubility and processability. Molecular Weight 207.03 g/mol: 2,6-Dichloro-3-Fluoro Acetophenone with a molecular weight of 207.03 g/mol is used in organic synthesis research, where it facilitates precise stoichiometric calculations and reproducibility. Stability Temperature up to 120°C: 2,6-Dichloro-3-Fluoro Acetophenone with stability up to 120°C is used in catalyst manufacturing, where it maintains chemical integrity under high-temperature conditions. Particle Size <50 μm: 2,6-Dichloro-3-Fluoro Acetophenone with a particle size of less than 50 μm is used in pigment production, where it enables enhanced dispersibility and color development. Low Moisture Content <0.2%: 2,6-Dichloro-3-Fluoro Acetophenone with low moisture content under 0.2% is used in electronic chemical synthesis, where it reduces hydrolysis risk and improves product shelf-life. Chromatographic Purity ≥99%: 2,6-Dichloro-3-Fluoro Acetophenone with chromatographic purity of 99% or higher is used in analytical standard preparation, where it ensures accurate calibration and measurement reliability. Refractive Index 1.56: 2,6-Dichloro-3-Fluoro Acetophenone with a refractive index of 1.56 is used in specialty coating formulation, where it contributes to optimal optical properties and surface finish. Boiling Point 238°C: 2,6-Dichloro-3-Fluoro Acetophenone with a boiling point of 238°C is used in solvent development, where it provides extended evaporation control and thermal stability. UV Absorbance λmax 285 nm: 2,6-Dichloro-3-Fluoro Acetophenone with a UV absorbance maximum at 285 nm is used in photochemical research, where it offers specific wavelength responsiveness for targeted studies. |
| Packing | The 100g package features an amber glass bottle, tightly sealed, with a hazard-labeled sticker indicating 2,6-Dichloro-3-Fluoro Acetophenone. |
| Container Loading (20′ FCL) | 20′ FCL container holds around 15–16 metric tons of 2,6-Dichloro-3-Fluoro Acetophenone, securely packed in UN-approved drums. |
| Shipping | 2,6-Dichloro-3-Fluoro Acetophenone is shipped in tightly sealed containers to prevent leakage, degradation, or contamination. It is typically transported as a solid under cool, dry conditions. Proper labeling and documentation are provided, complying with local and international regulations for the handling and shipping of hazardous chemicals. |
| Storage | 2,6-Dichloro-3-Fluoro Acetophenone should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from sources of ignition and incompatible materials such as strong oxidizers. Keep it protected from moisture and direct sunlight. Ensure the storage area is equipped with appropriate spill containment and clearly labeled for chemical safety. |
| Shelf Life | 2,6-Dichloro-3-Fluoro Acetophenone should be stored tightly sealed, protected from light and moisture; shelf life is typically 2-3 years. |
Competitive 2,6-Dichloro-3-Fluoro Acetophenone prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615651039172 or mail to sales9@bouling-chem.com.
We will respond to you as soon as possible.
Tel: +8615651039172
Email: sales9@bouling-chem.com
Flexible payment, competitive price, premium service - Inquire now!
After years of moving drums, measuring raw inputs, and checking each batch against rigorous standards, a compound’s value stands clear when chemists keep returning for it—even as their project timelines and product requirements shift. 2,6-Dichloro-3-Fluoro Acetophenone keeps showing up on those lists wherever specialized building blocks are required for pharmaceutical, agrochemical, or advanced material synthesis. This isn’t a chemical that gathers dust or sits in the catalog for show. Our production lines handle it regularly, and we know its quirks and its reliability in real-world processes.
With its molecular structure defined by dichloro and fluoro substitutions on the acetophenone core, this compound stands apart both in terms of reactivity and selectivity. Typical specifications from our plant run at a minimum purity of 98.5% by GC, a benchmark we arrive at through methodical distillation and refined crystallization. We do not cut corners on solvent stripping or filtration, because clarity, color, and solid residue tell us about stability—a light pale yellow crystalline powder signals a clean profile, free of side-isomers or over-halogenated impurities. Density, melting range, and volatility each tie back to our batch records. Strong chemical identity isn’t left to guesswork or just handled by a spec sheet—technicians in the quality control lab check IR, NMR, and mass spectra against authentic samples and historical references.
Our synthesis routes, developed and improved over several seasons, depend on careful chlorination and fluorination stages. These reactions demand close temperature control and patient quenching to avoid unwanted byproducts. Harsh reagents don’t like being hurried, so double rectification and multistep purification anchor our process. Every shift leaves behind operating notes—some of the best tweaks have come from line supervisors spotting a color change or drop in yield that didn’t fit the numbers on the monitor. We don’t skip corners on inert handling atmospheres or distillation for this compound. The result: reliable material for scale-up, pilot, or routine multitonne lots.
This isn’t a household chemical. Most chemists who contact us have downstream syntheses ready and waiting, with 2,6-Dichloro-3-Fluoro Acetophenone often forming the linchpin step in their process flow. It’s a favorite for introducing both chloro and fluoro motifs simultaneously—an advantage in medicinal chemistry where bioactivity hinges on subtle sterics and electronic effects. Aromatic acetophenones find roles as scaffolds for creating systemic crop protection agents and active pharmaceutical ingredients. Formulation chemists swear by the batch-to-batch reproducibility because early-stage R&D and late-stage validation both fall apart if intermediates wander off-spec.
Over the years, process scale-ups for contract manufacturers as well as global firms have necessitated tweaks in our process—sometimes tighter control on halide residuals, sometimes improved analytical documentation for regulatory filings. We’ve supported exploratory research where custom pack sizes cut down on exposure and waste, and we’ve worked with packaging specialists to prevent cross-contamination between halogenated ketones and less reactive stock.
With so many specialty fine chemicals circulating through world trade, names can become confusingly similar. Customers often ask: why choose a direct-from-the-plant supply line for 2,6-Dichloro-3-Fluoro Acetophenone, rather than generic sources or mixtures? From our end, traceability emerges at every step. Every drum gets labeling that links back to the exact reactor, shift team, and QC run. We troubleshoot questions about byproduct breakdown or trace impurities quickly, because production journals document raw material lots, supplier origins, and cleaning regimes for each synthesis cycle.
Some products on the market take short cuts with chronic trace-level isomers, or tolerate a haze of minor peaks in GC profiles that our protocol screens out. Customers who bring us those off-colour or yellow-brown competitor samples often report performance drift—unwanted side reactions, smell issues in pilot settings, or unexplained variability in crystallization. Years of feedback taught us that the “clean but not quite right” product eats more time and money than suppliers admit. More than any spreadsheet or glossy brochure, these repeated experiences led us to invest in purification and more frequent retention sampling.
Researchers aiming for high-value, functionalized molecules need starting materials that don’t introduce uncertainty downstream. We know academic and contract laboratories who work with us because of the real-world consistency that comes out of our reactors. Combining dual halogen functionality within a single acetophenone dramatically widens possibilities for further modification, yet also raises the stakes for batch uniformity. Downstream steps—nucleophilic substitutions, selective reductions, complexation—demand a precise arrangement of atoms and minimal extraneous material. Our batches have enabled medicinal chemistry programs to adapt in real time; scale-ups don’t stumble over latent impurities.
Some customers have told us that syntheses using competing material run into roadblocks—chromatography becomes a headache, telescoped routes deliver poor yields, and in one notorious case, downstream regulatory filings stalled over a trace impurity inconsistent with the reference standard. It doesn’t read like much on a spec sheet, but our attention to feedstock purity and careful documentation keeps these headaches miles away.
Feedback from the laboratory bench shapes our standard batches. Requests for lower residual solvents, smaller particle size, or pre-tested impurity panels have led to several changes on our production line. We don’t see specifications as static—our sales team and shift managers talk to clients at every scale, and small-batch requests that lead to an improved mainstream product. Several process engineers spend part of each month on the phone or video calls with customer chemists, discussing how our material behaves in their real environments.
Requests for tighter moisture control, especially for moisture-sensitive transformations, pushed our drying stage investments. Early batches didn’t always meet these stricter norms; feedback and stubborn repeatability challenges forced us to iterate. Some of the technologies, like in-line NIR moisture probes, originated from problem-solving efforts tied to real customer syntheses—not troubleshooting for its own sake.
Manufacturing and supplying a halogenated acetophenone on a continuous basis speaks to the challenges of chemical stewardship. We treat every kilogram of chlorinated and fluorinated byproduct as a resource to be reclaimed or safely neutralized. The regulatory landscape for halogen handling has grown more demanding; our plant routinely audits not only effluent streams, but also air handling and containment around our reactor vessels. We segregate streams with even trace levels of this compound to prevent inadvertent background exposure in unrelated syntheses—a single missed checkpoint can echo down a product line in both lost yield and confidence.
Strikes, raw material shortages, and logistical hiccups arise now just like they have for decades. What anchors our offering is simple—batch-quality consistency even when external variables shift. We manage supplier relationships for halogen sources and critical reagents by cultivating direct supply agreements and on-site buffer stocks. We maintain backup storage because surges in demand for agricultural offshoots or new pharma launches can trigger shipment requests weeks or months earlier than forecast.
The sharpest distinction for 2,6-Dichloro-3-Fluoro Acetophenone, compared with similar halogenated acetophenones, comes down to the placement and nature of those halogen atoms. Placing fluorine at the 3-position, against chloride at both 2 and 6 positions, tilts reactivity and lipophilicity—details that advanced chemists harness when trying to optimize lead candidates or fine-tune selectivity for synthesis. Some related analogues (monohalogenated, different halogen patterns) fail either the reactivity or stability requirements. We have seen customers try dual-chloro or mixed bromo analogues, hitting snags with solubility, side-reactions, or downstream customer approval.
Regular users have noted that switching to our high-purity variant cuts down on purification steps later. In one feedback session, a medicinal chemistry team in Europe halved their prep time on an intermediate because less baseline drift during HPLC freed up their automation bottleneck. This isn’t theory or margin-pushing marketing—customers routinely share how the difference shows up in batch time, solvent usage, and operator hours.
We have stood alongside research teams as they pivoted from pilot scale to routine manufacture, catching the production pinch when gram quantities balloon into kilos. Procurements go smoothly only if the supply keeps up, and those who’ve worked with anonymous suppliers often find they must bridge the gap themselves. Our familiarity spans from kilogram bottles for high-throughput screening to full-scale containers for contract or toll manufacturing setups. Short lead times and reliable pack sizes don’t result from luck; operators and logistics teams have hammered out their own hand-offs, avoiding stockouts and minimizing damaging delays.
We provide not just a batch, but an ongoing relationship built from hundreds of real-world challenges and fixes. Some facilities dealt with new analytical methods requiring cleaner backgrounds for regulatory review. Others found their scale-up steps mangled by previously unseen minor impurities. Both scenarios kicked off fresh problem-solving at our plant, with new filtration or analytical controls devised by our in-house chemists. We recognize patterns quickly, because a single unresolved impurity can shut down an entire production forum, risking expensive downtime.
Other suppliers sometimes promote alternative halogenated acetophenones or isomeric blends to laboratories and custom manufacturers. Often, these substitutes fail to match on reaction control or final product compliance. Reaction times extend, side reactions complicate purification, or regulatory teams flag batch variance at the documentation stage. Customers relay real losses in process throughput—extra steps, solvent washes, scrapped batches—cutting into both cost and research momentum.
From the manufacturing point of view, the reason is structural: our dual chloro and single fluoro in fixed positions delivers reactivity not easily mirrored by mixed or less pure batches. Competing processes often accept more isomer variance or broader impurity windows, hoping the end-user will compensate by adjusting reaction conditions. Our plant approach, scorched by years of similar problems, has always trended toward tight control over both the core product and common contaminants. Engineers on the line tie performance back to documented batch histories—not hope or assumption.
New entrants to the specialty acetophenone market sometimes claim high purity or “unique reactivity profiles,” but fail to back these assertions with clear traceability, reproducibility, and responsive supply. Reputation grows or falls based on customer experience—laboratories and process managers stick with suppliers when their pilot studies succeed and their big-batch paperwork doesn’t derail downstream. Our customer base has come to expect not only reliable material, but responsive troubleshooting and continuous documentation for regulatory, analytical, and scaling demands.
Some buyers require specialized COA formats, others need ongoing stability testing or environmental data collection for sustainable procurement protocols. These requirements add workload, but our team has found them invaluable in discovering and resolving issues long before they hit the application stage. Having worked through shifts where a late-identified reject batch nearly derailed an R&D program, our prioritization of traceability and routine documentation never relents.
On the plant floor, the best solutions come from adapting to issues, not ignoring them. For 2,6-Dichloro-3-Fluoro Acetophenone, most proactive improvements originated from recurring QC flags or direct user complaints. One year, odd residual moisture values on some mainline batches prompted a complete retooling of our drying ovens and sample handling. Another year, persistent reports of HPLC drift from a pharmaceutical client led to fresh staff training on cleaning and a round-robin sample exchange with their analytical team. Packing upgrades happened after realizing certain liner materials introduced background contamination—something not visible until subtle accumulations fouled downstream reactions.
We keep our process teams close to both the client lab bench and our own reactors. They spot trouble areas fast—stringent in-process checks, smart analytics, and day-to-day communication all contribute. Our improvements now come from shared knowledge: line managers presenting operational hiccups, analytical chemists flagging subtle shifts, and logistics coordinators closing feedback loops on delivery and traceability.
Our credibility as a manufacturer rests on a daily commitment: delivering a compound that performs across applications with no unpleasant surprises, no obscure side reactions, and a level of reliability that comes from constant attention on both technology and teamwork. 2,6-Dichloro-3-Fluoro Acetophenone exemplifies the value built from experience—not just technical specs, but from standing in the gap between a good enough batch, and a batch that repeats flawlessly, project after project.
Every kilogram carries the assurance earned from years of iterative improvements, direct client feedback, and the ability to solve tomorrow’s synthesis challenges by listening and adapting today. We optimize for outcomes—real-world downstream results for chemists who know the stakes and won’t settle for mystery byproducts, incomplete documentation, or uncertain supply.
Choosing a fine chemical like 2,6-Dichloro-3-Fluoro Acetophenone demands more than a spec sheet match or price comparison. Consistency, communication, and relentless iteration define what comes out of our reactors and how it enables your synthesis, day after day. Each reaction, each purified batch, and each documented solution embodies the direct lessons of chemical manufacturing, with pride in supporting both today’s and tomorrow’s discoveries.
