|
HS Code |
230915 |
| Cas Number | 320-50-3 |
| Molecular Formula | C7H3Cl2F3 |
| Molecular Weight | 215.00 |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | 164-166°C |
| Melting Point | -14°C |
| Density | 1.46 g/cm3 at 20°C |
| Flash Point | 58°C (closed cup) |
| Solubility In Water | Insoluble |
| Refractive Index | 1.507 |
| Vapor Pressure | 2 mmHg at 25°C |
| Synonyms | 2,5-DCBTF, Benzene, 2,5-dichloro-1-(trifluoromethyl)- |
| Odor | Aromatic |
| Stability | Stable under normal conditions |
| Purity | Typically ≥98% |
As an accredited 2,5-Dichlorobenzotrifluoride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 500 mL amber glass bottle with a sealed cap, labeled with hazard symbols and chemical details for 2,5-Dichlorobenzotrifluoride. |
| Container Loading (20′ FCL) | 20′ FCL: Loads about 13 metric tons of 2,5-Dichlorobenzotrifluoride, typically packaged in 250kg drums or IBC tanks. |
| Shipping | 2,5-Dichlorobenzotrifluoride is shipped as a hazardous chemical. It should be packed in tightly sealed containers, clearly labeled, and protected from physical damage. Transport must comply with regulations for hazardous materials, ensuring segregation from incompatible substances and avoidance of extreme temperatures, ignition sources, and moisture during transit. Proper documentation is required. |
| Storage | 2,5-Dichlorobenzotrifluoride should be stored in a tightly sealed container in a cool, dry, and well-ventilated area, away from heat, sparks, open flames, and incompatible substances such as strong oxidizing agents. Protect from physical damage, direct sunlight, and moisture. Properly label all containers and ensure chemical storage areas have appropriate spill containment and fire suppression systems available. |
| Shelf Life | 2,5-Dichlorobenzotrifluoride typically has a shelf life of 2-3 years when stored in a cool, dry, sealed container. |
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Purity 99%: 2,5-Dichlorobenzotrifluoride with purity 99% is used in pharmaceutical intermediate synthesis, where it ensures high yield and minimal by-product formation. Boiling point 180°C: 2,5-Dichlorobenzotrifluoride with boiling point 180°C is used in polymer manufacturing, where it provides stable processing conditions and controlled reactivity. Stability temperature 120°C: 2,5-Dichlorobenzotrifluoride with stability temperature 120°C is used in agrochemical formulations, where it delivers thermal reliability during storage and transport. Low moisture content: 2,5-Dichlorobenzotrifluoride with low moisture content is used in electronics coatings, where it prevents hydrolysis and improves coating uniformity. Density 1.48 g/cm³: 2,5-Dichlorobenzotrifluoride with density 1.48 g/cm³ is used in specialty solvent blends, where it offers optimal solvency and phase compatibility. Melting point -24°C: 2,5-Dichlorobenzotrifluoride with melting point -24°C is used in cold-weather pesticide production, where it maintains fluidity and ease of mixing at low ambient temperatures. Refractive index 1.48: 2,5-Dichlorobenzotrifluoride with refractive index 1.48 is used in optical resin manufacturing, where it contributes to precise optical clarity and light transmission. |
Competitive 2,5-Dichlorobenzotrifluoride prices that fit your budget—flexible terms and customized quotes for every order.
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People who work with fluorinated aromatics in labs or production lines will notice that not every benzotrifluoride handles the same. Those differences become obvious with experience running batch reactors, working with pilot-plant samples, or resolving technical issues on the shop floor. Through decades of manufacturing, storing, and shipping 2,5-dichlorobenzotrifluoride in quantities large and small, we’ve seen what this compound delivers and where it truly matters.
Our standard model for 2,5-dichlorobenzotrifluoride offers a typical assay above 99%. Most users expect a clear to pale yellow liquid, which quickly forms distinctive halogenated aromatics on reaction. Its boiling point gives an advantage in separation and recovery after use. The low water content and limited acid content allow for reactor feeds without extra purification steps. Over extended storage, sealed drums have shown no evidence of breakdown or color shift, providing confidence in raw material stocks even for heat- or light-sensitive applications.
Practical needs guide the demand for this molecule. Plants producing active pharmaceutical intermediates, crop protection compounds, or specialty fluorinated materials favor 2,5-dichlorobenzotrifluoride because it can drive reliable yields in halogen exchange and nucleophilic substitutions. In downstream chemistry, trifluoromethyl groups remain prized for imparting metabolic stability, lower surface energy, and unique electron-withdrawing effects. The presence of ortho and para chlorines further shapes the reactivity profile, offering substitution patterns that aren’t present in other dichloro or monohalo analogs.
We often field questions about whether this compound is a simple variant of other dichlorobenzotrifluorides, such as 3,4- or 2,6-. Technically, yes, several isomeric compounds exist, but physical properties and reactivity change with every change in ring position. Compared with 2,4-dichlorobenzotrifluoride, the 2,5- configuration can strike a better balance between steric hindrance and electronic activation, especially for metal-catalyzed cross-coupling or direct aromatic functionalization. This influence may not show up in a simple melting point table, but it will determine the result of a Suzuki or Buchwald-Hartwig reaction when every percent matters in scale-up.
From a manufacturing perspective, handling this compound goes beyond meeting a purity spec or hitting a color target. At bulk scale, the right material choices for tanks, pipes, and pumps prevent corrosion—chlorinated aromatics can put pressure on elastomers or gaskets that hold up fine with hydrocarbons, but falter under repeated contact with halogens or trace acids. Even in laboratory glassware, the right cleaning protocols matter, since residual organics or acids can degrade sample integrity. Our process engineers keep sample retention from every batch, allowing periodic quality checks to ensure shipping batches match original lots for viscosity, density, and GC profile.
On the technical side, our logs show that even small changes in drying time, vacuum quality, or distillation cut points influence downstream performance. Where some grades harbor subtle amounts of chloro- or fluoro-substituted byproducts, reaction selectivity can drop, or purification steps must increase, hitting project deadlines and costing valuable time. Running pilot batches alongside process development, our teams work directly with chemists to match specification to purpose—what works for a standard nucleophilic substitution may stumble in a catalytic process or for a pharma registration batch. These lessons translate into real guidance for formulating new generations of materials, not just theoretical insights.
Safety remains front-of-mind at every stage, from reactor charge to shipping manifest. Long-term experience confirms that, though non-flammable under normal handling, 2,5-dichlorobenzotrifluoride requires good ventilation and careful control at the loading dock and decant stations. Operators report that the vapor has a sharp, distinct odor, and even a small leak travels through a facility faster than some would expect. Standard PPE, organic vapor cartridges, and routine air monitoring deal with these exposures. In spill cleanups, its density and limited solubility in water mean proper diking and absorbent selection. Wastewater teams keep a close eye on effluent streams, and our environmental department coordinates routine emissions checks to maintain compliance with emerging fluorochemical regulations in North America, Europe, and Asia.
As public and regulatory scrutiny grows on persistent organic pollutants, producing and handling such compounds demands a solid environmental management system. We have invested in closed loading systems and vapor recovery units to minimize emissions at the plant. Spent drums undergo triple rinsing and safe disposal or recycling. Handling procedures stay under routine review, with regular drills, so everyone from operators to regulatory managers understands the potential impact of a release on site or in the community. The market has moved quickly—as new rules restrict certain classes of persistent fluorinated compounds, customers look for documentation on impurity profiles and assurances on end-of-life handling. Being upfront, solid traceability and a willingness to share complete analytical reports now matter as much as the actual batch purity or color.
As a manufacturer, the real challenge is never just producing a batch but making every drum, truck, and shipment live up to what’s on the spec sheet. Production volume for 2,5-dichlorobenzotrifluoride fluctuates more than many standard aromatics, as demand shifts with active ingredient launches, agrochemical registration cycles, or new material programs. To keep up, we have expanded tank farm and loading infrastructure, as well as added remote technical support. Our logistics team coordinates shipments with a focus on timeliness and compliance; this includes understanding which carriers meet all ADR or IMDG obligations and tracking every load for temperature and seal integrity.
We’ve improved tank designs with better corrosion resistance and more reliable nitrogen blanketing to stop moisture entry. Failure to maintain these steps in humid environments can result in hydrolytic breakdown. Routine audits have saved fresh stock from going off-spec due to small leaks or gasket failures. In the warehouse, warehouse staff rotate lots carefully so that customers receive the freshest possible material. We maintain long-term retention samples and re-verify quality in response to supply chain returns or customer inquiries, building trust that what is listed on the certificate matches what actually went into the process reactor or development lab.
Much has been said about purity, but in our production history, we’ve learned that 99% does not always mean no surprises. The analytical tools have evolved beyond GC area count to include NMR and mass spectrometry, providing a deeper look at trace levels of structurally similar byproducts. For critical customers who face increasingly tight regulatory demands, we offer additional data on elemental impurities, water, non-volatile matter, and residual solvents. Technicians regularly troubleshoot chromatographic trace peaks that, if ignored, could later complicate a downstream synthesis or trigger an unexpected odor or reaction outcome. These small differences are why repeat business depends on maintaining both technical rigor and transparency.
Customers sometimes ask if they can swap one grade for another. Our advice comes from hours in the plant and field — grades meant for agrochemical production sometimes carry trace metals or silicone picked up from storage tanks or commercial pipelines. For electronic materials or pharmaceutical synthesis, only high-purity lines, with continuous stainless steel or glass-lined contact, make sense. We maintain physical and digital batch records, tracing every kilogram back to its raw components and recorded processing steps.
Other suppliers might trade in intermediates or mix bulk from multiple origins. Our view comes straight from decades of vertical integration: we know how each starting material is sourced, how each reaction step proceeds, and what each process control metric does for the end product. We talk about “batch history” not as a buzzword but as a tool for understanding which batches run the cleanest, which stay within the tightest impurity limits, and when to screen raw materials for potential shifts in performance. Raw material quality, operator training, and in-process controls all matter — experience has taught us where the pitfalls lie, and how to avoid them before a batch ever leaves the plant gate.
The difference becomes clear in technical collaboration. We encourage customers developing a new synthetic route to provide feedback — not just at the order, but during active development. Customers have called in to share their GC traces or NMR spectra; our technical team has compared internal standards and checked batch logs to pinpoint the source of a troublesome impurity, sometimes going back a year or more. We share lessons learned from running pilot-scale or ton-scale processes, supporting the scale-up teams who depend on consistent feedstocks for success.
Many users ask how 2,5-dichlorobenzotrifluoride compares to related products. From laboratory and industrial work, the key differences emerge in terms of reactivity, substitution patterns, and storage or transport needs. The 2,5- ring substitution offers a balance between reactivity and selectivity that some chemistries demand. For instance, nucleophilic substitutions on fluorinated rings respond differently to ortho- and para-chloro substituents; certain syntheses benefit from the unique electronic effects of the 2,5- compound, especially when targeting high-value intermediates.
Other dichloro isomers, such as 2,4- or 3,4-, show different melting points, boiling points, and rates of reaction under similar conditions. These distinctions can affect the yield of biaryl coupling or the speed and selectivity of halogen-lithium exchange. Over the years, we have worked with customers to trial multiple isomers under actual process conditions before settling on 2,5- for its combination of cost, availability, and technical performance. Transition-metal catalyzed processes, those relying on tight control of substitution patterns, and programs seeking to minimize side-reactions have found advantage in our 2,5- product line. In practical terms, using the wrong isomer can mean extra purification or failed reactions, as those subtle electronic and steric differences show up, not just on paper, but in plant yields and daily operations.
Real progress comes from joint experience, shared between plant operations teams, lab chemists, and the people who load the drums and monitor the trucks. Over time, we’ve collected invaluable feedback — chemists who switched to our material and found their residue levels dropped, or engineers who reduced downtime by eliminating storage corrosion. Issues such as container compatibility, reaction reproducibility, and impurity carryover matter not only in thousands of liter batches but in milligram scaleups for new product launches. Every resolved problem brings insights, and every challenge underscores the importance of ongoing dialogue between supplier and customer.
Typical feedback highlights the reliability of our supply chain during periods of sudden demand or regulatory change. Our technical support team helps with questions on handling, reaction troubleshooting, and efficient solvent recovery. New applications, such as advanced materials or specialty fine chemicals, often push us to develop new quality benchmarks, and our willingness to invest in analytical upgrades or process improvements keeps us at the front of the field. We use customer input not just as after-action review but as the fuel for process improvement—new corrosion inhibitors, bulk tank upgrades, and procedural changes stem from lessons learned with every order shipped and every new project supported.
The world of chemicals is never static. New government rules target fluorinated organics, downstream manufacturers chase lower impurity levels, and regulatory burdens only increase. Our experience as a manufacturer puts us in a position to guide customers through technical and compliance questions. We review changing regulatory frameworks, such as EU REACH updates or new Asian environmental standards, and cooperate with external auditors and customer safety teams alike. Documentation, batch traceability, and open communication have avoided costly production delays and regulatory hurdles for our partners. The challenge is constant, but trust is built batch by batch, test by test, and shipment by shipment.
As manufacturing conditions evolve, customers demand more precise specifications, reduced environmental footprints, and support in developing greener downstream solutions. Our plant managers and R&D teams remain committed to continuous improvement, seeking cleaner synthesis routes, greater process control, and more efficient use of energy and raw materials. We watch advances in analytical chemistry, follow new developments in catalyst technology, and actively collaborate with university and industrial partners on innovative applications. Whether users need drum quantities for established processes or first lots for developmental chemistry, we stand ready to meet new challenges and share what the years have taught us: consistency, quality, and real service only come with the lived experience of making, not just selling, each kilogram of 2,5-dichlorobenzotrifluoride.
In short, our journey with this compound reflects a commitment to accuracy, transparency, and shared technical progress, ensuring customers get a solution shaped by real-world lab and plant results, not just a product listing. That’s what makes a genuine difference every day in how 2,5-dichlorobenzotrifluoride is made, delivered, and trusted.
