|
HS Code |
741019 |
| Name | Titanium diisopropoxide bis(ethylacetoacetate) |
| Chemical Formula | C18H36O8Ti |
| Cas Number | 27858-32-8 |
| Molecular Weight | 440.35 g/mol |
| Appearance | Yellow to orange liquid |
| Density | 1.07 g/cm3 |
| Solubility | Soluble in organic solvents |
| Purity | Typically ≥75% |
| Storage Temperature | 2-8°C (refrigerated) |
| Sensitivity | Moisture sensitive |
| Refractive Index | 1.463 (20°C) |
| Flammability | Combustible |
| Smiles | CC(C)OC(=O)CC(=O)OCC(C)C.O=C(CC(=O)OC(C)C)O[Ti](OC(C)C)(OC(C)C)OC(=O)CC(=O)OC(C)C |
As an accredited Titanium diisopropoxide bis(ethylacetoacetate) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Titanium diisopropoxide bis(ethylacetoacetate), 100 mL, is packaged in a sealed amber glass bottle with a secure screw cap for protection. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for Titanium diisopropoxide bis(ethylacetoacetate) typically involves secure drum or IBC packaging, maximizing safety and volume. |
| Shipping | Titanium diisopropoxide bis(ethylacetoacetate) is shipped in tightly sealed containers under nitrogen or dry atmosphere to prevent moisture contamination. It is classified as a hazardous chemical and must be transported in compliance with regulations, with proper labeling and documentation. Storage and handling should avoid heat, moisture, and ignition sources. |
| Storage | Titanium diisopropoxide bis(ethylacetoacetate) should be stored in a tightly sealed container under an inert atmosphere, such as nitrogen or argon, to prevent hydrolysis. Keep it in a cool, dry, and well-ventilated area, away from moisture, heat sources, and incompatible materials like acids and oxidizing agents. Store at ambient temperature or as specified in the supplier’s instructions. |
| Shelf Life | Titanium diisopropoxide bis(ethylacetoacetate) typically has a shelf life of 1–2 years when stored tightly sealed under inert atmosphere. |
Competitive Titanium diisopropoxide bis(ethylacetoacetate) prices that fit your budget—flexible terms and customized quotes for every order.
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Every day on the production floor, we monitor more than just reactors and filling lines—we watch for trends in what our partners ask for in high-performance materials. Over the past several years, Titanium diisopropoxide bis(ethylacetoacetate)—often called Ti(iPrO)2(acacEt)2—has attracted attention well beyond the traditional academic or pilot-scale sectors. Our teams work with this product directly, batch after batch, and that gives us a clear view of what truly matters in both its manufacture and its downstream applications.
We ship Titanium diisopropoxide bis(ethylacetoacetate) with a minimum purity of 98%. Every drum, from the first liter to the last, reflects clean synthesis, careful purification, and closed-system packaging. Customers rely on narrow spec windows because small variations, even on the scale of tenths of a percent, can completely derail a thin-film coating run or disrupt a sol-gel process in advanced ceramics. Our approach in production doesn’t focus on pushing for absolute purity at the expense of cost—the real focus is repeatable, verifiable output that matches what users expect whether they order a single drum or a full-container load.
A clear yellow liquid at room temperature, this titanium chelate remains stable under recommended storage, though we always advise keeping it moisture-free. Even small levels of moisture start hydrolysis and change both the reactivity and appearance—early signs come as a gel or haze, and any technician who’s cleaned out a fouled feed line knows chemical control here pays for itself tenfold.
In practical terms, the products leaving our plant typically ship with densities around 1.09 to 1.13 g/cm3, and Ti content by weight falls close to 10%. Experienced users focus less on these numbers as abstractions and more on how predictable handling supports their end goals. At the drum scale, volatility and reactivity are immediate concerns. Our synthesis and bottling lines operate under nitrogen, and only clean, dry stainless transfer lines touch the finished compound, which cuts the risk of unannounced water cheating its way in.
Some customers run these specs for each delivery and compare against their own internal standards, but from years watching feedback, they value a supplier who invests not just in analytics but in process controls where variability simply doesn’t start in the first place. In this market, certificates aren’t paperwork to check a box; they’re evidence of why one drum equals the next.
Most people who work with Titanium diisopropoxide bis(ethylacetoacetate) aren’t remote from the action. The demand often centers around precise coatings and functional films, particularly in sol-gel chemistry, CVD (chemical vapor deposition), and catalysis setups. In our plant, we see the diversity of end-users directly—some from semiconductor labs, some from display technology factories, others from fiber-optic material developers.
In the high-grade coatings world, hydrolysis and condensation reactions form the backbone of titanium oxide film creation. Unlike some harsher titanium alkoxides, this molecule releases its ligands in a more controlled manner, offering gentle processing conditions. When operators tune hydrolysis rates by picking different precursors, this chelated form reduces unpredictable side-products and allows for greater maneuverability in adjusting film thickness and refractive index.
Researchers and process engineers point out that this chelate’s dual modification—both diisopropoxide and bis(ethylacetoacetate) ligands—alters its reactivity compared with pure titanium isopropoxide or unmodified titanium acetylacetonate. This flexibility can prove crucial: for titania films, a little more stability in the solution state prevents premature precipitation and improves coating uniformity on glass or SiO2 wafers.
Catalysts using titanium centers also depend on subtle changes in ligand architecture. In our own bench tests and through customer pilot-scale runs, Titanium diisopropoxide bis(ethylacetoacetate) shows higher selectivity for some oxidative transformations compared with simpler titanium esters. The ethylacetoacetate groups make more room for substrate approach in homogeneous catalysis routines, and some partners, especially in custom organics, have noted improved yields after switching away from the more classical titanium(IV) isopropoxide.
Titanium chemistry offers plenty of choices, but not all options serve the fine-tuned demands of modern coatings and advanced materials. A standard grade of titanium isopropoxide, for example, reacts rapidly with even trace moisture and can give uneven deposition, localized over-reaction, and pore formation, especially at the pilot-to-production scale. This leads to wasted runs and expensive filter or vessel cleaning.
Titanium diisopropoxide bis(ethylacetoacetate) behaves differently—its chelating ligands slow down and moderate hydrolysis and condensation. Teams running multi-step deposition sequences take advantage of this by stretching process windows and improving control over both thickness and crystallinity in their output films. For chemists producing TiO2 nanoparticle dispersions, this means less unwanted agglomeration and cleaner phase transitions during calcining steps.
In comparison to titanium(IV) acetylacetonate, which brings even more stability but sacrifices some reactivity, our product strikes a practical balance. Operators realize better handling throughout storage and transport, and reactivity levels unlock easier integration into aqueous or mixed-organic systems. Safety improves, since runaway reactions become less likely than with classic alkoxides, allowing less stress around air/water ingress on the plant floor.
For us as the manufacturer, reproducibility in ligand structure and clean byproduct removal make a tangible difference. Unreacted starting materials or excess ligands leave fingerprints—distinct odors, changed viscosities, color shifts—which line operators notice well before an instrument reports a drift in spec. Years in the plant have taught our crews what every real user learns: it’s not about what’s on the MSDS, it’s about what that drum does every day on your line.
People buy reassurance as much as product. In our plant, we run full computerized traceability for every batch of Titanium diisopropoxide bis(ethylacetoacetate) shipped. That starts with identity and purity checks, but the real guarantee grows from controlled reaction times and temperature profiles, handled by teams who have run this same synthesis for years.
Our experience shows that details matter—product stored at the correct temperature stays color-stable. Valves, gaskets, and tote liners selected for compatibility avoid small but costly introduction of contaminants. Teams conducting routine in-process retests catch even minor drifts in the UV/Vis absorbance that signal early-stage oxidation or midstream hydrolysis. These extra steps add up to batches that behave more predictably in your reactors and coaters, saving both money and time for people with real throughput needs.
We have years of data confirming shelf life when stored under dry, sealed nitrogen—up to twelve months without breakdown, provided temperatures remain below 25°C and sunlight stays off the packed drums. Some customers request specialized secondary containment or multi-barrier drums for offshore shipping, and our experience adapting to these requests cuts down risk and post-arrival loss.
On the shop floor, one lesson repeats: don’t take shortcuts. Titanium diisopropoxide bis(ethylacetoacetate) needs sealed, dry nitrogen blankets through every transfer. Even five minutes of open headspace in humid air will start a cascade into gel or white precipitate. That means proper PPE, closed-system pumps, and double checks before each connection. Regular sampling using gas-tight syringes takes a bit longer but preserves batch quality over months, not days.
Solvent compatibility tests save headaches, too. Some users favor isopropanol as a flush or dilution solvent, and our process data supports this, though fresh batches of anhydrous solvent work best. Avoid common tap solvents—trace salts and dissolved oxygen both interfere with clean film-formation and lead to black speckling or unwanted phase shift in ceramic output. Having these basics built into operator training routines boosts equipment lifespan and reduces total solvent overhead, lessons won in both our own production lines and customer troubleshooting sessions.
We send full documentation on recommended transfer and storage protocols, tailored not as sales points but as lessons earned from actual process failures and recoveries. These go beyond general HazMat handling and focus on the operational realities that separate flawless runs from costly re-batches.
Clients in the photovoltaic sector have taught us the value of product reliability at scale. Their feedback after switching from titanium tetraisopropoxide to our product centers on predictable film thickness and transparency, both essential for maximizing panel efficiency. Labs running prototyping for sensors and electrochromic devices report smoother deposition and fewer pinhole defects—important metrics on both performance and cost-per-unit.
Bulk users in fiber technology draw consistent tensile properties after switching to this titanium precursor, noting reduced clogging in spinnerets and decreased maintenance downtime. Although our focus is manufacturing and not end-use research, these outcomes come through in the way buyers reorder and the way their QA managers interact with our batch data.
Some teams in the specialty adhesive and surface treatment space use this product to anchor organic residues or provide robust linkage between glass and polymer substrates. Our own experiments with joint ventures have shown a marked improvement in final product curing and hardness profiles, opening possibilities not easily achieved with older titanium chelates.
Years of making, packaging, and shipping this compound reveal the practical decisions that shape adoption. End users care less about theoretical advantages and more about the reduction in unplanned downtime, improved control over hydrolysis, and safety record in real use. Plant engineers running line-scale adoption value closed-system technical guidance, not just parameter tables. Our support teams grew up on-site before moving to technical support, so their recommendations draw from both the classroom and the trenches.
Sustainability matters too. By reducing the incidence of off-spec batches and reworks, we minimize waste upstream; by supporting higher-yield film formation and lower defect rates, we help clients downstream cut scrap and lower their environmental footprint. Real progress comes from long-term plant partnerships—no one wants a “fire and forget” chemical solution that leaves troubleshooters chasing ghosts for months.
Supply chain reliability matches quality for importance. Our clients want reassurance that each shipment, whether in peak season or during logistics crunches, will look and perform like the last. That means local storage solutions, backup tankers, and rapid response protocols for any batch anomalies.
Every manufacturer encounters breakdowns—ours included. Looking back on the last decade, we’ve learned from mistakes in temperature controls, failed cylinder seals, and incorrect batch coding more than from any success story. Early on, one storage run shipped after extended exposure to warm conditions en route; we tracked field complaints as drums formed precipitate and the solution clouded before application. These incidents shaped our current storage and logistics policies, from rapid QC retesting after unloading to redesign of our container venting.
We’ve also adapted our fill lines to handle small-batch specialty transfers for R&D-scale users, reducing the minimum order size and improving lead times for partners who need flexibility. Listening to feedback and observing how customers actually use the product exposed little details, such as the importance of clear lot traceability and the need for calibrated glassware for in-lab dilution.
Down the line, tighter controls on in-process sampling and end-point distillate checks have become daily practice. These checks detect off-odors or slight changes in the refractive index before the product reaches the user, reducing downstream losses and speeding up root cause analysis if an issue pops up.
Ongoing R&D aims to extend shelf life even in less-than-ideal field conditions, challenging the limits of stabilization chemistry. We’re also exploring sustainable synthesis pathways with lower waste profiles and greener solvents, looking for ways to retain performance while shrinking the overall environmental toll.
Our teams exchange data with major academic and industrial research groups, ensuring production practices keep pace with both safety advances and new application demands. We watch trends in downstream industries—like rising interest in flexible electronics and advanced coatings for medical devices—and tune our product qualities and batch sizes around these evolving needs.
Direct manufacturing brings accountability. Only a plant making its own Titanium diisopropoxide bis(ethylacetoacetate) can invest in batch-by-batch process improvement, catching problems at the source and building institutional knowledge instead of relying on paperwork. Over time, that shows in lower rejection rates, higher customer trust, and fewer supply chain hiccups.
We support both standard and special-use blends, shipping with direct technical input from the team that produced the batch. Our solution doesn’t end at the drum; users talk to the chemists who designed the process, not a distributor reading off the back label.
Innovation in coatings, electronics, and catalysis keeps raising the bar for precursor quality. Titanium diisopropoxide bis(ethylacetoacetate) appeals to those balancing performance, cost, and safety—not just on paper, but in reactors and production lines worldwide.
Our history with this compound means more than maintaining a tight spec—it means recognizing that user priorities shift over time. Whether scaling up for commercial rollouts or optimizing for a one-off research application, we’re in a position to adapt blend ratios, packing, and support documents faster and with more accuracy than third parties.
Buyers working at the leading edge of chemistry know they need a manufacturing partner with both technical mastery and an eye for practical constraints. Our experience shows that technical agility and open communication matter just as much as classic purity metrics. The right titanium precursor, handled by people who know its quirks and details, lifts yield and reliability at every stage of production.
