|
HS Code |
495892 |
| Chemical Name | 4-Iodophenyl Ether |
| Molecular Formula | C6H5IO |
| Molar Mass | 236.01 g/mol |
| Cas Number | 637-41-6 |
| Appearance | White to off-white solid |
| Melting Point | 56-59°C |
| Boiling Point | 273°C |
| Density | 1.91 g/cm3 |
| Solubility In Water | Slightly soluble |
| Purity | Typically ≥98% |
| Storage Conditions | Store in a cool, dry place |
| Synonyms | p-Iodophenyl ether |
| Smiles | C1=CC(=CC=C1OC)I |
| Inchi | InChI=1S/C6H5IO/c7-6-3-1-2-5(4-6)8-9/h1-4H |
As an accredited 4-Iodophenyl Ether factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
|
Purity 99%: 4-Iodophenyl Ether with purity 99% is used in pharmaceutical intermediate synthesis, where it enables high reaction yields and reduced impurities. Molecular weight 250.01 g/mol: 4-Iodophenyl Ether with molecular weight 250.01 g/mol is used in fine chemical manufacturing, where it ensures precise stoichiometric calculations and product consistency. Melting point 46°C: 4-Iodophenyl Ether with melting point 46°C is used in solid-state formulation studies, where it facilitates controlled melting and recrystallization. Stability temperature 80°C: 4-Iodophenyl Ether with stability temperature 80°C is used in thermal processing applications, where it maintains chemical integrity under moderate heat. Low water content <0.2%: 4-Iodophenyl Ether with low water content <0.2% is used in moisture-sensitive cross-coupling reactions, where it minimizes unintended hydrolysis and decomposition. Particle size D90 <50 µm: 4-Iodophenyl Ether with particle size D90 <50 µm is used in homogeneous catalyst preparations, where it enhances dispersion and reaction surface area. Viscosity grade low: 4-Iodophenyl Ether with low viscosity grade is used in organic electronic material formulation, where it improves processability and film uniformity. Assay ≥98%: 4-Iodophenyl Ether with assay ≥98% is used in agrochemical synthesis, where high purity ensures reproducible product outcomes. Spectral grade: 4-Iodophenyl Ether with spectral grade is used in analytical reference material preparation, where it delivers accurate and consistent spectroscopic results. Solubility in ethanol >10 g/L: 4-Iodophenyl Ether with solubility in ethanol >10 g/L is used in solution-phase chemical reactions, where it provides efficient reactant dissolution and mixing. |
| Packing | The 4-Iodophenyl Ether is packaged in a sealed 25-gram amber glass bottle with a secure screw cap and chemical hazard labeling. |
| Container Loading (20′ FCL) | Container loading (20′ FCL) for 4-Iodophenyl Ether involves safely packaging, labeling, and securely stowing drums or bags for export transport. |
| Shipping | **Shipping Description for 4-Iodophenyl Ether:** 4-Iodophenyl Ether should be shipped in tightly sealed containers, protected from light and moisture. It must be handled as a chemical reagent and transported according to local, national, and international regulations. Ensure proper labeling, use suitable secondary containment, and include documentation of hazard classification for safe delivery. |
| Storage | 4-Iodophenyl Ether should be stored in a tightly closed container in a cool, dry, and well-ventilated area, away from direct sunlight and incompatible substances such as strong oxidizing agents. Ensure the storage location is secure and clearly labeled. Keep the chemical away from sources of ignition, heat, and moisture to prevent decomposition or hazardous reactions. |
| Shelf Life | 4-Iodophenyl Ether typically has a shelf life of 2–3 years when stored in a cool, dry, and tightly sealed container. |
Competitive 4-Iodophenyl Ether prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615380400285 or mail to sales2@liwei-chem.com.
We will respond to you as soon as possible.
Tel: +8615380400285
Email: sales2@liwei-chem.com
Flexible payment, competitive price, premium service - Inquire now!
In nearly two decades spent at the heart of specialty chemical production, earning the trust of pharmaceutical developers and advanced material researchers has required more than bulk supply. Precision, reliability, and understanding customer needs have shaped how we approach every molecule, especially our 4-Iodophenyl Ether. Over the years, colleagues debated tweaks to the process, shifts in raw input, and the right way to test each lot before shipment. These little battles matter since every batch produced holds the end application’s success in its hands.
Working with aryl iodides and substituted phenyl ethers draws in those who value reactivity, traceability, and a level of purity that shaves hours off purification at the customer site. 4-Iodophenyl Ether, or as some clients refer to it by its systematic name, 1-iodo-4-phenoxybenzene, offers a distinct gateway for further functionalization through coupling reactions. Our production line focuses on reaching and maintaining a purity over 98%, confirmed through HPLC and NMR checks. The pale solid nature, coupled with predictably stable melting characteristics, makes this compound easy to integrate into solid-phase transformations or to weigh out with minimal fuss.
What clients often mention after switching to our material concerns more than a chemical’s published values. Experienced chemists quickly spot low-level traces of residual halides or poorly controlled moisture content in commodity supplies. We source precursors based on a decade-long mapping of consistent suppliers and maintain batch records extending back to the earliest runs. Each stage, from hydrogen iodide monitoring to etherification, gets tracked with modern QC — no shortcuts to speed up yield if it risks purity or consistency.
As a building block, 4-Iodophenyl Ether slots into the world of medicinal chemistry and new class catalyst explorations. Medicinal research teams picked it up for synthesizing biaryl scaffolds and fitting custom substituents on benzene backbones using palladium-catalyzed cross-couplings. A handful of agrochemical customers rely on it as a precursor in synthesis chains. Electronic material firms turn to it for complex monomer systems that require the fusion of aromatic rings without heavy contamination. This material stands out for those seeking a reactive iodine leaving group paired with an oxygen bridge that brings in a different layer of chemical flexibility.
Outside the textbooks, buyers sometimes try to cobble together similar molecules in their own labs, only to run into repeated headaches over side products, inconsistent batch behavior, and purification time sinks. Years ago, one medium-sized customer in Europe switched from local sourcing to our facility after three pilot runs failed to generate enough high-quality product for scale-up. Instead of focusing on patchwork solvent recovery protocols, their team restarted their process with our ether and reached target yields with cleaner profiles almost overnight.
Many lab catalogues provide a string of aryl halides and ethers, but not every option holds its integrity under tough reaction or storage conditions. What genuinely distinguishes our 4-Iodophenyl Ether is the methodical removal of possible contaminants—the low ppm levels of free halogen or trace acids—without running up cost or lead time. On a visit last year to a longtime client, the lead scientist put a fine point on this: “If we need to spend all week cleaning up starting material, we aren’t innovating — we’re cleaning.” That mindset shapes every step. Instead of being content with average purity, our technicians verify each batch using in-house analytics, not third-party contractors, so nothing leaves our site unless it meets our direct standards.
Compared to cheaper analogues like chlorinated or brominated phenyl ethers, 4-Iodophenyl Ether brings unmatched reactivity to many coupling protocols. The iodine atom acts as an unusually responsive leaving group under conditions that fail to shift less reactive halides. Chemists chasing tough, sterically hindered couplings find smoother progress with our ether than with similarly structured chloride or bromide variants. Difference on a bench scale might look minor, but moving to pilot or kilo scale magnifies those subtle shifts into order-of-magnitude differences in cost, byproduct load, and downstream waste management.
Our emphasis on material characterization reaches beyond regular purity. Moisture content control — verified by Karl Fischer titration — matters if a customer’s catalyst system is water-sensitive. We run gas chromatography on every batch to confirm prospective volatile organics stay below detectable limits. Each certificate comes with a full analytical trace, not just a one-line purity statement, because time after time, client feedback made it clear that detailed, manufacturer-level documentation saves project delays and unexpected outcomes.
Routine in specialty chemical manufacturing means never resting on old standards. From the earliest days, orders trickled in from researchers facing bottlenecks. For several years, a major pharma partner in the US struggled with variable yield on their coupling reactions—a challenge tracked down to inconsistent input quality from a previous supplier’s inconsistent purification scheme. After we reviewed their data and supplied reference analytical spectra directly from our library, they resolved ongoing process issues and streamlined repeat synthesis for two major development programs.
Our facility scaled up output after learning which points in the process tempted short-cuts. Temperatures, solvent ratios, and minute changes in crystallization can spell the difference between a chromatographically clean product and a run filled with stubborn baseline drags. Regular pilot runs and keeping seasoned staff on the reactor line catch subtle deviations early. Our chemists revisit analytics any time client specs shift, and after major plant upgrades, we requalify each product line—never assuming old process recipes fit new equipment styles.
This is a hands-on business. Over the years, batch records grew thicker and documentation protocols expanded to satisfy regulatory and customer scrutiny. On one occasion, a batch flagged for an off-normal melting point held up a shipment, leading to lengthy internal and client-side troubleshooting. After root-cause analysis and test reruns, we improved our mixing step, rewrote procedures, and reduced future lot variations by half. Experience tells us that even seasoned manufacturers must keep listening, testing, and staying ready to fix overlooked process nuances.
Working hand-in-hand with researchers, contract manufacturers, and supply chain managers, we see new projects push our technical capabilities. For synthetic pathway design, 4-Iodophenyl Ether offers a modular starting point for a range of unique transformations: Suzuki-Miyaura couplings, etherifications, and oxidative rearrangements. Teams in pharmaceutics look for minimal impurity profiles since trace metals or decomposed side-chains can sabotage sensitive downstream reactions. We respond by implementing extra purification stages and pulling random retention samples for cross-lab validation. Investing in robust raw material traceability and mapping each production parameter lets us troubleshoot collaboratively with clients when something unexpected arises.
Flexibility on batch size and delivery timing gained significance during the pandemic years, when global logistics stretched thin. Our in-house logistics group adapted, including custom packaging and division across multiple lot shipments to protect customer R&D schedules. We handled urgent dispatches for time-sensitive pilot manufacture runs, even redirecting material between countries by air freight when local border policy shifted. Teams on our production side maintained transparent updates, setting clear expectations so customers could plan their own operations around realistic delivery forecasts rather than vague promises.
Supporting downstream teams means sharing technical expertise drawn from the plant floor, not repeating generic copy. When clients report unusual side product patterns or yield drops, our team reviews their protocols and historical supply data. In one case, a major client discovered persistent off-color product during their hydrogenation step—right down to minor pinkish tints. A joint root-cause review pinpointed slightly higher residual metals from one of their reagents, long before their own QA lab’s LOD checks. Our analytical support, built up by troubleshooting hundreds of real-world campaigns, enabled rapid process redesign and cleaner end products.
Handling aryl iodides and specialty ethers involves attention to chemical stewardship at every stage. Operational directives at our manufacturing site go beyond base regulatory compliance. By recovering process solvents through multi-stage distillation and re-evaluating waste streams, we reduce environmental impact and control emissions. Ongoing updates to containment and operator handling cut down on material loss and avoid cross-contamination. Chemists in large volume production know even small spillages or leaks can cost dearly—both financially and environmentally—so we invest in best-in-class containment, monitoring, and personal training.
We work closely with hazardous goods logistics partners to comply with transit protections. Before each package departs, our team double-checks that material labels, containment, and shipment documentation match destination requirements. Every staff member that directly handles raw material or finished product trains on hazard identification, chemical compatibility, and incident response, learning from industry case studies as well as our own experience.
Over years spent scaling output and answering demanding questions from global clients, we learned that credibility isn't built from stock language or promises. Real-world results — documented, tracked, open for review — shape our company reputation and long-term partnerships. Many returning customers cite our transparency and direct communication as essential to their project continuity. Most set their spec sheets based on years of collaboration, adapting their protocols to our actual measured values instead of marketplace averages.
Late-stage synthesis rarely forgives substandard starting materials. Research and manufacturing clients burned by low-quality supply chains come through our doors every quarter, some with stories of missed pilot launches and chronic purification problems. As a chemical manufacturer, the only sustainable approach is to own the molecule’s lineage from raw input selection through reactor protocol, handling, and logistics—all tracked under real accountability.
Working directly with buyers, technical directors, and procurement specialists, we invest time walking through each specification change, formulation adjustment, and market shift. No batch ships without detailed analytics and traceable records, because we expect partners to hold us as responsible as their own in-house teams. That attention draws a sharp line between a manufacturer’s commitment to quality and the unpredictability of brokered supply.
For those building processes that rely on the power and selectivity of aryl iodides, and who cannot afford rework cycles or wasted pilot material, our plant stands ready to partner. The legacy of consistent 4-Iodophenyl Ether production depends not on glossy brochures but the lived experience of hundreds of batches, thousands of kilograms, and technical feedback loops reaching across continents and industries. As projects become more complex, the value of direct manufacturer dialogue and complete process insight will only deepen. In this business, experience and detail do the talking.
