|
HS Code |
308558 |
| Cas Number | 609-09-6 |
| Molecular Formula | C8H14O3 |
| Molecular Weight | 158.19 g/mol |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | 186-187°C |
| Density | 0.98 g/cm³ at 20°C |
| Refractive Index | 1.417-1.420 at 20°C |
| Flash Point | 75°C |
| Solubility In Water | Slightly soluble |
| Odor | Fruity, ester-like |
As an accredited Ethyl 2-ethyl-3-oxobutanoate:Diethyl acetoacetate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 500 mL clear glass bottle with a tamper-evident cap, labeled "Ethyl 2-ethyl-3-oxobutanoate:Diethyl acetoacetate, CAS 609-14-3, 500 mL". |
| Container Loading (20′ FCL) | **Container Loading (20′ FCL)**: Ethyl 2-ethyl-3-oxobutanoate:Diethyl acetoacetate, packed in 200 kg drums, typically loads 80 drums (16 MT) per 20′ FCL. |
| Shipping | Ethyl 2-ethyl-3-oxobutanoate (Diethyl acetoacetate) should be shipped in tightly sealed containers, protected from light and moisture. Store at room temperature in a well-ventilated area, away from ignition sources and incompatible materials. During transport, comply with all local and international regulations for chemical shipping, including appropriate hazard labeling and documentation. |
| Storage | **Ethyl 2-ethyl-3-oxobutanoate:Diethyl acetoacetate** should be stored in a tightly closed container in a cool, dry, well-ventilated area away from heat, ignition sources, and incompatible materials such as strong oxidizers and acids. Protect from moisture and direct sunlight. Store at room temperature or as recommended by the manufacturer, and ensure container is properly labeled to prevent accidental misuse or exposure. |
| Shelf Life | Ethyl 2-ethyl-3-oxobutanoate:Diethyl acetoacetate typically has a shelf life of 12–24 months when stored properly in sealed containers. |
Competitive Ethyl 2-ethyl-3-oxobutanoate:Diethyl acetoacetate prices that fit your budget—flexible terms and customized quotes for every order.
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At our manufacturing plant, Ethyl 2-ethyl-3-oxobutanoate has earned a respected reputation among specialty esters and industrial intermediates. Decades of hands-on experience guide every step, from raw material selection through to purification and packaging. We produce this compound in batches using esterification of high-purity acetoacetic acid derivatives, ensuring a consistent molecular structure and low impurity profile. The focus always stays fixed on reliability and consistent output, both of which support downstream customers in demanding businesses like pharmaceuticals and fine chemicals.
Every lot we release adheres to specifications tested internally before leaving the warehouse. Key metrics—such as purity, residual solvent, and water content—receive direct, instrument-based verification using established methods. We track every stage with a documented chain of custody, and every operator receives targeted training to reduce the risk of crossover contamination—a detail that becomes crucial for downstream performance.
The mainstream grade we offer arrives as a clear or slightly yellowish liquid. Most clients care about purity in excess of 98 percent, a low moisture content, and minimal acidic or basic impurities. These attributes affect reaction yields and downstream product consistency, which is why we spend significant resources monitoring them from raw material intake. Storage stability rounds out the key features; the liquid needs to remain true to specification during standard shelf-life periods at room temperature, always in tightly sealed drums or IBCs. We run accelerated stability testing as part of our regular protocol to verify that even under less-than-ideal shipping conditions, properties like boiling range, acidity, and ester content hold their ground.
Some partners request extra-dehydrated lots or bespoke filtration to support applications in pharmaceutical synthesis, particularly where trace impurities might degrade catalysts or skew analytical outcomes. Having fine-tuned filtration and refining facilities on-site, we field these requests directly. Instead of sending out sub-lots for third-party finishing, our staff handles specialized runs with the same care used for primary production.
One trend seen through years of orders is the diverse applications for Ethyl 2-ethyl-3-oxobutanoate. Pharmaceutical companies pull our material into the synthesis of key building blocks—for example, as precursors for pyrazoles, pyrimidines, and custom heterocyclic scaffolds. Agrochemical firms use it as a foundation for selective herbicides, and dye manufacturers employ it for coupling reactions that rely on clean, reproducible intermediates. Through feedback and shared process data, we understand that reliable, batch-certified material reduces trial-and-error at our customers’ end, saving both time and resources.
Direct engagement with our customers shapes specifications. An early customer highlighted an issue with trace peroxides affecting sensitive hydrogenation catalysts. Instead of passing off the problem, we evaluated and updated the polishing process at our site to deliver peroxide levels below actionable thresholds. That change now benefits the wider user base, as all future lots flow through the new protocol.
Although the terms Ethyl 2-ethyl-3-oxobutanoate and Diethyl acetoacetate are sometimes mixed up, they differ in both chemical structure and downstream reactivity. Diethyl acetoacetate offers utility as a classic acetoacetate ester, finding its way into C–C bond formation, pigment synthesis, and pharmaceutical intermediates. Ethyl 2-ethyl-3-oxobutanoate, distinguished by an added ethyl group on the central carbon, brings increased branching. Chemists leverage this structure to modulate reactivity and physical properties. For example, the extra branching can influence solubility in organic solvents and alter reaction selectivity during alkylation or acylation steps.
These differences affect both the manufacturing complexity and the logistics of storage and shipment. We dedicate production lines to each type, preventing cross-contamination and ensuring no confusion in shipping or labeling. Product codes, labeling conventions, and certificates of analysis remain rooted in clear chemistry, reflecting exactly what the end user receives.
Differences also surface in pricing, not only due to raw material costs but also due to demand cycles and regulatory review timelines in pharmaceutical applications. For some processes, customers have pointed out that reactivity profiles are enough to dictate a total switch from diethyl acetoacetate to ethyl 2-ethyl-3-oxobutanoate, especially when pursuing patents on new synthetic methodologies or targeting specific molecular frameworks for API development.
As the manufacturer, we bear the weight of consistency on every delivery. Chemists testing purity and composition use techniques like gas chromatography, titration, and Karl Fischer moisture checks. Instead of outsourcing responsibility, our staff owns every run from the inside out. Equipment calibration happens on a rolling schedule, and our on-site QA technicians keep reference samples on hand from each lot in long-term storage. This historical sample archive often proves valuable. A customer once encountered a downstream issue with a reaction yield, so we pulled archive samples and re-ran the analysis to investigate possible contamination. This open sharing of data and methods preserves trust and keeps incremental improvement ongoing.
Documented process controls shield every batch from unexpected excursions. Staff rotate between production and QA assignments to increase their familiarity with critical control points. These firsthand insights help staff recognize subtle changes in color, odor, or viscosity that fall outside specification—long before any instrument might sound an alert. Practical knowledge built case-by-case, over years in the factory, shapes our ability to catch the rare off-spec lot before it leaves the gate.
Raw materials drive everything, and quality always links back to origin. Most of our starting compounds come from within the region, keeping supply chains short and transparent. Facility managers track sources, and routine supplier audits get built into the year’s calendar. In seasons when one supplier faces capacity issues, backup networks built over years of partnership swing into action. The industry’s shift toward greener chemistry requires smart thinking too. Our research department watches emerging routes and benchmarks catalyst recycler programs, searching for improvements that might benefit both our operation and environmental profile.
Some partners ask about the sustainability footprint of our products. We welcome these questions and invite them to review life-cycle analysis reports tied to major process steps. Recently, our teams trialed a process solvent recovery upgrade, slashing waste by more than twenty percent on annual throughput. This cut not only reduces disposal costs, but also improves product cost stability for customers. These upgrades stem from real-world experience and accountability—not outside reporting requirements.
Few processes run perfectly from textbook to plant floor. Every so often, a customer encounters a stubborn impurity, a sticky phase separation, or logistical hiccups. We never rely on distant outside consultants to diagnose these cases. Production engineers, research staff, and QA managers take customer process data directly and propose tweaks from experience—altering charge weights, sequencing washing steps, or adjusting heating ramps as needed. These improvements have, over time, led to new SOPs and internal standards. We see technical exchange as both a duty and an advantage.
Some manufacturers struggle with the bottleneck of lab-to-production scale-up, especially for custom grades or first-time orders for an exotic application. Our facility maintains pilot reactors for small-scale experiments before moving to full-scale runs. This flexibility provides experimental data to customers who may need to see how a blend holds up or whether a change in process speeds throws off the impurity profile. The double feedback loop—getting actual customer input and feeding plant data back—results in a quieter complaint line and stronger order repeat rates.
In an industry sometimes dominated by commodity haggling or mystery intermediaries, production transparency becomes the competitive edge. Every field visit, order history, and returned sample feeds lessons back into how we plan production lots. Several years ago, during an especially turbulent logistics season, a courier strike delayed Europe-bound shipments for days. Our crew coordinated alternate rail lines and rolled out an SMS update service to keep overseas customers in the loop. By the time the strike ended, most buyers were already rebooked thanks to updated delivery forecasts—minor in the scheme of things, but a reflection of our commitment to direct lines of communication. Years later, some of those same clients still comment on how those real-time updates helped avoid lost hours in packed plants.
Shipping liquid intermediates creates unique challenges that often fly under the radar. Tank containers need dedicated cleaning certificates, and every connector or gasket can become a risk for contamination. We keep in direct touch with logistics partners, tracking each movement, monitoring for possible temperature fluctuations, and incorporating GPS monitoring on higher-value consignments. This chain of vigilance—starting with raw material dock and ending with the customer’s drum—catches slight deviations before they threaten production runs downstream.
Across the globe, regulatory frameworks keep shifting. Well-resourced manufacturing plants bear the brunt of constant updates, from regional transport labeling to evolving international safety standards. When regulations change, our compliance staff works late rounds reviewing batch traceability, re-certifying packed goods, and re-aligning document trails. Compliance audits—from both internal checks and customer sources—get welcomed rather than sidestepped. Instead of simply preparing paperwork, we share on-site walkthroughs and data access, fostering a spirit of shared correctness.
For our pharmaceutical and agrochemical customers, failings in regulatory documentation can stall approvals and scuttle entire projects. So, as manufacturers, we bake this diligence into every step—from developing SDSs with up-to-date language to maintaining audit trails on every run of Ethyl 2-ethyl-3-oxobutanoate and Diethyl acetoacetate. During audit season, our facility hosts more than twenty groups walking the floors, reviewing environmental controls, and talking to production teams face to face. It’s the direct experience of answering technical questions—without script or delay—that upholds trust.
Over the years, customer feedback has shaped everything from process adjustments to new batch release criteria. One significant case developed after a customer trialed our material and discovered that a minor aldehyde impurity, rarely flagged in routine screens, tripped up a subsequent reduction step. Drawing on firsthand experience, our technical and QC teams collaborated to isolate and eliminate the source, updating purification sequences and eventually adopting it plantwide. A fix born from direct collaboration, not an outside troubleshooting memo.
Face-to-face meetings have often spurred deeper improvements. Some customers fly their technical staff to our facility, inspecting reactors, sampling material, and observing daily quality checks. These sessions break down barriers—both in technical exchange and mutual expectations. Shared meals and plant walk-throughs often yield better process tweaks than email chains, bringing human context to technical requirements. Ultimately, the strength of these relationships rests on trust—built batch by batch and handshake by handshake.
Most staff in our plant have rotated through at least two technical roles before settling into a specialty. From experience, they know that technical solutions earn their staying power only after being vetted against full-scale production. When a new use case arrives—a customer asks if Ethyl 2-ethyl-3-oxobutanoate holds up under a novel hydrazine-coupling reaction or whether Diethyl acetoacetate can scale to a thousand-liter batch without phase drift—our on-site experts guide the discussion and, if needed, recreate parts of their protocols for testing.
No process or compound functions as a silver bullet. We map real-life limitations and practical workarounds for the benefit of every buyer. This realism prevents both disappointment and wasted time; our advice stems from daily shop-floor realities, backed by empirical data. From freeze-thaw resilience to shelf-life extension protocols, we unpack both strengths and manageable quirks in each product, letting clients design their own margins of safety.
While technology and demand will keep evolving, the role of a primary manufacturer won’t shrink. Each batch reminds us how much hinges on honest process, direct communication, and technical learning earned through decades of work. The tools may grow more sophisticated—more in-line sensors, more data flow—but in the end, it remains the human element that sorts a passable batch from a lot destined for champion status.
Whether a customer reaches for Ethyl 2-ethyl-3-oxobutanoate or Diethyl acetoacetate, their focus stays the same: they want confidence in every drum, open traceability, and direct human expertise within reach. Year after year, this drives our crew to fine-tune every process, dig deep into analysis, and keep learning both from our own missteps and customer triumphs. From this cycle of improvement and responsibility, customers draw their own confidence—knowing the supply chain starts with an accountable, transparent source.
