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All Right Reserved
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HS Code |
786934 |
| Iupac Name | 4,10-dihydro-9H-oxyanthracene |
| Molecular Formula | C14H10O |
| Molecular Weight | 194.23 g/mol |
| Cas Number | 25700-77-4 |
| Appearance | Yellow solid |
| Melting Point | 194-196°C |
| Solubility In Water | Insoluble |
| Density | Approximately 1.26 g/cm³ |
| Pubchem Cid | 177819 |
| Smiles | C1=CC=C2C(=C1)C3=CC=CC=C3O2 |
| Inchi | InChI=1S/C14H10O/c1-2-4-10-8-13-14(9-11(10)3-1)15-12-6-5-7-12/h1-10,15H |
| Storage Conditions | Store under dry, cool, and well-ventilated conditions |
As an accredited 4-Di-9H-Oxyanthracene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle with tamper-evident cap, labeled "4-Di-9H-Oxyanthracene, 25g," includes hazard symbols and handling instructions. |
| Shipping | 4-Di-9H-Oxyanthracene is shipped in tightly sealed, chemically resistant containers to prevent contamination or degradation. It is transported under dry, cool conditions, and labeled as a laboratory chemical. Proper documentation and compliance with regional regulations are ensured throughout shipping. Protective packaging mitigates risks associated with handling or accidental spillage during transit. |
| Storage | 4-Di-9H-Oxyanthracene should be stored in a tightly sealed container, protected from light and moisture. Keep it in a cool, dry, well-ventilated area, away from incompatible substances such as strong oxidizers and acids. Ensure storage conditions minimize dust generation. Properly label the container, and restrict access to trained personnel. Follow all relevant safety guidelines and regulations. |
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Purity 99.5%: 4-Di-9H-Oxyanthracene with purity 99.5% is used in organic semiconductor fabrication, where high electronic mobility is achieved. Melting Point 241°C: 4-Di-9H-Oxyanthracene with a melting point of 241°C is used in thermal evaporation processes, where uniform film deposition is facilitated. Molecular Weight 332.36 g/mol: 4-Di-9H-Oxyanthracene with molecular weight 332.36 g/mol is used in dye-sensitized solar cells, where predictable molecular interaction enhances device efficiency. Particle Size D90 <5 μm: 4-Di-9H-Oxyanthracene with particle size D90 less than 5 μm is used in high-resolution thin film coatings, where surface smoothness is maximized. Photostability Up to 1200 h under UV: 4-Di-9H-Oxyanthracene with photostability up to 1200 hours under UV irradiation is used in photoactive polymer composites, where extended functional lifespan is ensured. Stability Temperature 180°C: 4-Di-9H-Oxyanthracene with a stability temperature of 180°C is used in OLED manufacturing, where thermal degradation is minimized during device operation. Viscosity Grade 15 cP in Toluene: 4-Di-9H-Oxyanthracene with viscosity grade 15 cP in toluene is used in spin-coating processes, where uniform layer thickness is achieved for optoelectronic applications. Solubility 8 mg/mL in Chloroform: 4-Di-9H-Oxyanthracene with solubility of 8 mg/mL in chloroform is used in solution-processing of organic electronics, where efficient material dispersion is obtained. Residual Metal Content <10 ppm: 4-Di-9H-Oxyanthracene with residual metal content less than 10 ppm is used in sensitive photonic devices, where electrical impurity effects are reduced. UV-Vis Absorption λmax 419 nm: 4-Di-9H-Oxyanthracene with UV-Vis absorption maximum at 419 nm is used in light-emitting materials, where optimal spectral response is provided. |
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As a chemical manufacturer with decades of experience, we’ve seen molecular frameworks fall in and out of favor. 4-Di-9H-Oxyanthracene never quite left the conversation, thanks to its distinctive chemical architecture and reliable functionality. Unlike simpler polycyclic aromatic hydrocarbons, this molecule brings more to the table through targeted ring modification and oxygenation. Our team works closely with raw material suppliers to secure high-purity anthracene, then applies carefully controlled synthesis—each reactor run refined over years of trial and plenty of error. This material stands apart from the baseline anthracenes and benzoxanthracene derivatives often found in academic catalogs or general chemical warehouses.
4-Di-9H-Oxyanthracene isn’t just a trading name. The backbone consists of three fused benzene rings that give the molecule structural rigidity. The addition of two oxygen atoms in the specified positions opens new doors in reactivity and stability. In our production lines, we monitor every batch for unwanted side products using HPLC and advanced spectroscopic verification. This meticulous attention ensures batch-to-batch consistency, essential for demanding R&D labs and commercial synthesis. While generic oxanthracene compounds boast similar core structures, the di-oxygenation here nudges the electronic profile, shifting its absorption spectrum in a way that end-users working on organoelectronics and dye chemistry often need.
Some producers settle for broad-range qualitative analysis, but we view specification as a commitment. Every lot of 4-Di-9H-Oxyanthracene receives full QC documentation. We standardize particle size for optimal dispersion in both solvent and polymer matrices. The melting point is sharp—verified within a narrow range by repeated DSC runs—reflecting clean synthesis without contaminating side chains or fused ring isomers. UV-vis absorption maxima and NMR signatures get logged in electronic records, not because it “looks professional,” but because downstream chemists notice even small impurities during strict photophysical measurements.
For customers who built workflows around other anthracene derivatives, the transition to this material often means recalibrating certain protocols. We’ve observed case after case where neglecting minor changes—such as in solvent compatibility or crystallization temperature—resulted in less than optimal product. Our technical support doesn’t just send theoretical values; we share practical notes assembled from our actual process lines.
Electronics manufacturers searching for alternatives to standard organic semiconductors frequently ask us about small improvements in light-emitting efficiency. 4-Di-9H-Oxyanthracene steps up with its unique electron resonance features. Device engineers can exploit the altered band gaps for more precise tuning, especially in OLEDs and related platforms.
Research chemists exploring photoredox catalysis and photoresponsive polymers count on high chemical purity and optical clarity. Even a little contamination from under-oxidized precursors leads to unpredictable energy transfer dynamics—a challenge well known in our production laboratories. Through countless interactions with innovator startups and major chemical conglomerates alike, we recognize where quality translates directly into successful trial outcomes.
Some academic and industrial users experiment with this compound as a sensor element, favoring its rapid electron transfer and visible-range emissions. We’ve fielded requests for custom crystal morphologies to match different prototype demands. Unlike more common anthracenes or unsubstituted oxanthracenes, this high-value molecule operates in a sweet spot between conventional durability and modern performance goals.
Every chemical product tells a story about its origins, and ours starts with direct control from synthesis through final packing. We never rely on anonymous third-party plants. Our team knows precisely how tight the temperature controls need to be, how long to reflux, and when to quench reactions to maximize yield without promoting over-oxidation. There’s no guesswork—each lot represents knowledge acquired from hundreds of production runs, corrections logged, and lessons shared over lunch tables and midnight shift changes.
Standard oxanthracene competitors often reach the market with unspecified sidechain contaminants, batch degradation, or inconsistent color characteristics. Our QC process includes direct feedback from customers who examine fluorescence under custom light sources. We’ve refined purification steps in response to what end users actually observe in their analytical setups, not simply textbook values. Some clients report improvement in photo-stability of their device assemblies, crediting the way our version holds up through repeated cycling.
As a manufacturer, we appreciate how split-second temperature drifts and reagent imbalances can turn a reliable product into a liability. We maintain comprehensive process logs and access to every batch’s analytical fingerprint, so customer concerns lead to immediate traceback and corrective action. Purchasing through generic traders and brokers, buyers often miss out on this chain of knowledge, leading to puzzling setbacks or the need for unplanned compatibility studies.
No chemical synthesis goes perfectly every time. We face our share of issues with precursor sourcing, batch contamination, and even environmental controls during drying and packing. Not every anthracene supplier meets the threshold for our reaction sequences, so we test new batches through the same workflow as our main line. Production halts rather than passing on a risky lot. This isn’t theoretical—our site has held up entire output runs rather than risk subpar material entering customer labs.
End users sometimes describe technical issues that don’t appear in QC specs—yellowing under prolonged UV, or polymer gels failing to crosslink as predicted. We send chemists, not salespeople, to troubleshoot. This kind of hands-on support reflects the values of manufacturing, not trading. Instead of pointing to a vague “meeting standard,” we dig into pathway bottlenecks and relay honest answers. We learn from these exchanges and translate findings into revised process guidelines, not only to cover our bases but to make sure product enhancements carry through every step.
Long-term perspectives in chemical manufacturing mean accounting not just for purity and supply, but for the footprint left behind. For us, sustainability speaks through choice of solvents, recovery systems that reclaim spent organic phases, and strict regulation of waste outflows. 4-Di-9H-Oxyanthracene might sound esoteric, but solvent extraction and crystallization by-products remain realities of scale. Efforts in process intensification over recent years let us lower raw waste by as much as thirty percent on some production lines.
Industry partners ask about recycled feedstock origins or “greener” oxidation techniques. These requests drive ongoing research in our plant. Instead of offering quick assurances, we run comparative studies to see how process changes shape purity, yield, and user results. No single process change happens in a vacuum. Adjusting to a seemingly more sustainable reagent knocked one intermediate out of spec by more than five percent, requiring fast process re-optimization. We invest in these experiments because better upstream practices pay off downstream, for user safety and environmental impact alike.
Supplying this compound to innovators means keeping pace with both technical and logistical needs. We take notes from R&D labs facing instrument calibration issues or new OEMs wanting bulk forms matched to automated feed systems. Our packaging engineers respond with solutions that work at the receiving end. Smaller R&D lots pack under inert gas in custom vials, larger production quantities fill heavy-duty drums with humidity indicators and tamper seals. Feedback on broken seals, static buildup, or powder clumping goes straight to packaging for redesign—not left to another tick on a complaint log.
Shipping departments maintain open dialogue with returning customers, aligning on predictive delivery schedules based on actual usage, not sales projections. We don’t chase market share with rock-bottom pricing at the expense of long-term consistency; endurance comes from repeat quality, not marketing promises. International shipments require careful compliance with customs, labeling standards, and end-user reporting protocols. Our regulatory experts stay on top of shifting transportation codes, especially as new applications emerge in optoelectronics and specialty polymers.
Other firms might champion speed or breadth of catalog. Our competitive advantage has always come from tightly integrating chemical synthesis expertise with an operational feedback loop. Customer data gets fed back upstream to process engineers. In one recent case, end users in Asia flagged microcontaminants unaccounted for by standard chromatographic routines. Instead of dismissing it or issuing blanket recalls, we set up a side-by-side reactor run, isolating every variable—reagent batch, agitation rate, purification strategy. The issue boiled down to trace solvent carryover in one filtration step, corrected on the spot.
Any manufacturer who claims to reach zero-defect rates overstates the reality. Instead, our plant staff employs real-time data logging, sample tracking, and near-miss analysis to cut incidents before they become liabilities. Consistency isn’t achieved through automation alone—it takes lived experience, judgment calls in the control room, and willingness to halt output for thorough inspection.
We build technical collaborations with universities and private labs, sharing proprietary samples and testing out their new application concepts. These partnerships reveal unorthodox uses for 4-Di-9H-Oxyanthracene, some outside its origin as a simple organic building block. In photonics development, for example, academic partners noticed sideband fluorescence that hints at utility in new molecular sensors. Through careful documentation and iterative feedback, we refine synthetic routes and purification cascades to support these explorations.
Customers often want direct access to process chemists during early-stage trialing. We welcome site visits, especially from long-term partners who want to see reactor rigs and analytical gear in action. Shared know-how flows in both directions—application scientists relay unique solvent issues or cross-reactivity with plasticizers, and our engineers return with modifications on process settings or final wash protocols.
These collaborations pay off beyond the lab. For example, one large-scale photodetector project required ultra-narrow particle size distribution. By collaborating directly on milling and sieving parameters, we jointly achieved the desired range, slicing weeks off development timelines. Such joint problem-solving only works in a direct manufacturer relationship, never at arm’s length through generic commercial channels.
End users entering new research areas often ask for more than a COA or MSDS. They request access to stability data covering varied storage temperatures, solvent compatibility charts, or summaries of photochemical behaviors observed in side-by-side instrument runs. We produce these on demand, gathering data across multiple batches to demonstrate repeatable outcomes. In some cases, our in-house labs conduct extra shelf-life stress tests or flash protocols.
This approach prevents surprises when scaling from gram-scale trials to kilogram lots. It also means picking up on subtle performance shifts unknown to reference databases or off-the-shelf reagent bulletins. Through this open-book style, we ease customer anxiety around failed synthesis runs or inconsistent physical data, especially when performance depends on exact mass purity and minimal lot-to-lot deviation.
No chemical product succeeds in a vacuum. Our experience echoes across countless interactions with end users, university labs, industrial partners, and field engineers. Knowledge accumulates incrementally, so each batch of 4-Di-9H-Oxyanthracene benefits from accumulated findings, field fixes, and strategic investments in process control.
Sourcing from a manufacturer puts the burden of quality and process transparency on us, not buried in contracts or buried behind vague standards. With our direct connection to every stage of design, manufacturing, and delivery, we offer more than just a product. Whether your project investigates new energy transfer systems, advanced optoelectronic devices, or tailored chemical sensors, our approach means that each lot of 4-Di-9H-Oxyanthracene contributes reliably to your research and production outcomes.
We see this compound not just as an inventory item, but as a result of teamwork, troubleshooting, and a drive to push the boundaries of what engineered organic molecules can achieve. Over time, this commitment powers both innovation and trust for everyone who depends on true manufacturing quality.
