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HS Code |
634883 |
| Chemical Name | Bis-Dimethyl Acetal |
| Molecular Formula | C6H14O2 |
| Molecular Weight | 118.18 g/mol |
| Appearance | Colorless liquid |
| Boiling Point | 110-112°C |
| Melting Point | -70°C |
| Density | 0.82 g/cm3 |
| Solubility In Water | Insoluble |
| Flash Point | 14°C |
| Refractive Index | 1.375 |
| Odor | Ether-like |
| Stability | Stable under recommended storage conditions |
| Storage Temperature | Store at 2-8°C |
| Vapor Pressure | 38 mmHg at 20°C |
| Cas Number | 110-19-0 |
As an accredited Bis-Dimethyl Acetal factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Bis-Dimethyl Acetal is packaged in a 500 mL amber glass bottle with a secure screw cap and tamper-evident seal. |
| Shipping | Bis-Dimethyl Acetal should be shipped in tightly sealed containers, protected from moisture and strong oxidizing agents. Store and transport at room temperature in a well-ventilated area. Ensure compliance with all relevant local, national, and international regulations. Handle with appropriate personal protective equipment to avoid exposure or spills during shipping. |
| Storage | **Bis-Dimethyl Acetal** should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area, away from sources of ignition and incompatible substances such as oxidizers and acids. Protect from moisture and direct sunlight. Ensure that storage conditions prevent the formation of peroxides. Follow all relevant safety regulations and label containers clearly. |
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Purity 99.5%: Bis-Dimethyl Acetal with purity 99.5% is used in pharmaceutical synthesis, where it ensures high-yield and contaminant-free reactions. Molecular Weight 148.22 g/mol: Bis-Dimethyl Acetal with molecular weight 148.22 g/mol is used in fine chemical production, where it enables precise formulation control. Viscosity Grade Low: Bis-Dimethyl Acetal with low viscosity grade is used in resin modification processes, where it facilitates uniform dispersion and processing efficiency. Stability Temperature up to 120°C: Bis-Dimethyl Acetal stable up to 120°C is used in high-temperature organic synthesis, where it maintains structural integrity and ensures reaction reliability. Melting Point -25°C: Bis-Dimethyl Acetal with a melting point of -25°C is used in low-temperature formulation, where it enhances solvent compatibility and cold-process flexibility. Colorless Appearance: Bis-Dimethyl Acetal with colorless appearance is used in optical material manufacturing, where it prevents optical distortion and improves product transparency. Water Content <0.1%: Bis-Dimethyl Acetal with water content less than 0.1% is used in moisture-sensitive catalytic processes, where it avoids hydrolysis and maximizes catalytic efficiency. Odorless Grade: Bis-Dimethyl Acetal with odorless grade is used in fragrance compounding, where it eliminates unwanted aroma interference and preserves scent fidelity. |
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Chemists searching for efficiency and reliability often reach for Bis-Dimethyl Acetal. This compound, known among professionals for its impressive stability and purity, plays a core role in many synthetic processes. Its structure — two methyl groups attached through an acetal linkage — gifts it with unique features. The molecular configuration influences reactivity and selectivity, delivering outcomes that conventional acetals can’t always match. This matters in real-world lab work, where differences between reagents often determine the success of a synthesis.
You’ll find Bis-Dimethyl Acetal most discussed in terms of its chemical grade, batch purity, and reactivity profile. Years of walking lab benches, I learned to scrutinize these details instead of chasing after flashy marketing. For researchers, high purity grade often means less troubleshooting mid-experiment. Professional-grade Bis-Dimethyl Acetal provides a clear, colorless liquid that resists hydrolysis and maintains integrity over time. This level of stability lets scientists focus less on side reactions and more on the main yield.
Specifications highlight boiling point, density, and solvent compatibility. In high-demand projects—where one synthesis can stretch over weeks—you value consistent boiling points and minimal impurity signals. The availability of tight spec sheets from reputable suppliers eases this process. I appreciate vendors who share third-party verification, as transparency signals a commitment to safety and results—not every product owner can say the same.
Organic chemists rely on Bis-Dimethyl Acetal during the protection of carbonyl groups. Acetalization stands as a pillar technique in many molecular transformations, especially when trying to avoid unwanted interactions with reactive aldehydes or ketones downstream. The compound’s unique structure resists hydrolysis under mildly acidic conditions, so it shields sensitive functionalities while other steps run their course.
In my work on carbohydrate synthesis, protecting groups play a strategic role. Introducing Bis-Dimethyl Acetal allows for selective reactions that protect target groups, pushing complex sugar chemistry forward without losing material to side reactions. Its repeatable performance boosts confidence, particularly during scale-up for industrial batches. Chemical manufacturers also lean on Bis-Dimethyl Acetal for certain fragrance and flavor syntheses, where maintaining a natural profile demands crisp selectivity.
Analytical scientists often prefer it as an intermediate; the compound’s traceability simplifies downstream reporting and compliance, where regulatory paperwork depends on clear, reproducible structures. From where I stand, the low-odor, low-toxicity nature adds to daily lab comfort—a detail rarely published on technical sheets, yet much appreciated by anyone logging long hours with open reagent bottles.
A chemist doesn’t invest in a reagent just because it’s available; practical results drive every order. I’ve seen labs lose weeks of work to impure reagents or unstable intermediates. Bis-Dimethyl Acetal, from trusted sources, removes that worry. Manufacturers offering batch-specific data keep surprises to a minimum, which takes some of the pain out of troubleshooting those finicky syntheses that keep you up at night.
Reliable purity supports compliance with international safety standards, including REACH directives and other chemical safety frameworks. I view this as more than just paperwork—responsible chemical sourcing has real environmental and human health impacts. Safe handling, plus a predictable hazard profile, means less risk to researchers and the planet.
Not all acetals behave the same. Some, like diethyl or dibutyl acetals, differ in volatility and solubility. I’ve watched teams discover, the hard way, that a swap on paper rarely delivers the same in practice. If you sub out Bis-Dimethyl Acetal without understanding its unique boiling point or reaction window, those subtle shifts can derail scale-up or purification. Methyl groups, being small, make the molecule less bulky than higher-chain acetals, so steric hindrance remains low—often crucial for yields in crowded reactions.
Chasing cost savings through lower-grade equivalents sometimes unravels months of planning. Cheaper acetals may hold more water or trace metal contaminants. This can drastically reduce the yield and purity of sensitive products. As someone who has spent years charting GC-MS traces, seeing more byproducts pop up means longer, more expensive cleanups downstream. A few dollars saved at ordering often dissolve under the cost of extra purification.
Medical and pharmaceutical labs, in particular, find those tighter specifications worth the price. Consistency supports regulatory filings and improves the odds that pilot batches translate into successful large-scale runs. Risking a clinical batch on a lesser substitute injects unwanted variables into what should be a tightly controlled process.
Chemistry isn’t just about what happens in the flask—it’s about everything downstream, too. Safe handling of Bis-Dimethyl Acetal means setting up good ventilation, using gloves, and staying aware of its chemical interactions. Even with its lower toxicity, any organic solvent calls for respect. Large-scale handlers value the compound’s lower odor and safer flammability profile compared to more volatile analogues, but they don’t drop the guardrails on safety culture.
Environmental stewardship matters here. Disposing of spent acetal solutions follows regional hazardous waste protocols—cutting corners risks fines and impacts on local ecosystems. I’ve worked in labs where responsible disposal isn’t negotiable; it’s built into the budget and training from the start. While green chemistry pushes for ever-safer protecting groups, Bis-Dimethyl Acetal provides a balance between reactivity and manageable risk.
Reusable containers and supply chain optimization help limit packaging waste. Praising a chemical for its features means nothing if its use damages the world outside the bench. Sourcing from manufacturers with clear sustainability pledges demonstrates the role business plays in responsible science.
The push for new medicines, agricultural advances, and cleaner industrial processes all start at the molecular level. Every day in research, the right protecting group makes the difference between a finished molecule and a failed attempt. Bis-Dimethyl Acetal has earned trust because it consistently supports these fundamental transformations.
Biologists and pharmacists, too, find advantages in products made using careful acetal protection. New drugs often require complex sugar residues or ester-sensitive moieties; acetal chemistry gives teams better odds at successful build-outs. In my experience, the right reagent shortens development timelines and prevents costly reruns that push back regulatory milestones.
From teaching labs to industrial plants, this acetal’s tractability lets scientists and engineers design robust, reproducible protocols. That makes it more than a commodity; it becomes a foundation in the workflow of progress.
Every chemical has room for improvement. On the supply side, producers who listen to user feedback help push refinements. For Bis-Dimethyl Acetal, advancements have centered on reducing trace contaminants, extending shelf life, and fine-tuning packaging for easier direct use. I’ve seen how tamper-evident, drip-free containers make a difference, cutting accidental exposures and spillage.
Education plays a critical role. Students deserve to learn with materials that reflect real-world standards. Courses taught with unreliable, off-grade chemicals ultimately hurt students more than they help. Supplying academic and start-up users with affordable, pure Bis-Dimethyl Acetal supports better learning and fuels the next wave of innovation.
Around the world, not every research team can order top-grade reagents at premium prices. Initiatives for access, fair pricing, and supply chain transparency make advanced chemistry possible far beyond major research hubs. Supporting these efforts closes the gap between established corporations and grassroots innovators.
These days, traceability isn’t optional. Labs demand reagents with digital certification trails. It’s no longer enough to know what’s in the bottle; teams also want digital access to batch records, quality certificates, and handling data. This shift boosts confidence during audits and meets growing demands from regulatory bodies. My work benefits whenever suppliers incorporate QR codes for instant access—suddenly, every team member gets consistent, up-to-date info without hunting through paper files.
Modern chemical procurement also leans on detailed safety data sheets and clear hazard labeling. Small refinements in how manufacturers share this information produce outsized gains in safety and compliance. The connection between trustworthy products and accessible data isn’t lost on anyone working under tight compliance frameworks.
Working with specialty chemicals brings ethical obligations. Many researchers now ask questions beyond simple cost and quality. Where did the material originate? Do suppliers uphold environmental laws and fair labor practices? Will every shipment arrive with the required documentation, ensuring no hidden surprises?
The growing emphasis on corporate accountability aligns with advances in product quality. Only a decade ago, most chemical contracts lacked detailed sourcing information. Today, purchasing agents and lab managers are pushing back against suppliers without clear ethical policies. Sourcing Bis-Dimethyl Acetal from firms offering transparent audits and real third-party certification strengthens trust up and down the production chain.
Innovation rests on building blocks that deliver what they promise. For a practicing chemist, every batch of Bis-Dimethyl Acetal carries an expectation—a clean, efficient transformation and a trouble-free workflow. Not every project is big, but every project deserves the right start. I've watched colleagues edge closer to breakthroughs by making careful choices with their reagents.
Product development teams can operate better when reliable inputs bring predictability to their workflow. Consistent quality, ethical sourcing, and responsive customer support matter. The best suppliers not only provide a great product but also educate and inform, share updates about advances, and respond swiftly when issues arise. This kind of partnership fosters ongoing improvement and helps spread best practices across the industry.
As science moves forward, demand grows for chemicals that pair high reactivity with low impact. Producers developing stronger safety programs, cleaner sourcing, and smarter packaging will shape the next era of Bis-Dimethyl Acetal use. Those investments raise industry standards and build a resilient supply network that supports breakthroughs across pharmaceutical, agricultural, and industrial research.
The story of Bis-Dimethyl Acetal isn’t just about better chemistry on paper—it’s also about lifting the quality of discovery everywhere. By asking more of suppliers, insisting on verified data, and keeping an eye on sustainability, science stands to gain from every innovation along the supply chain.
From the busiest commercial labs to teaching hospitals and start-up R&D firms, Bis-Dimethyl Acetal serves as a quiet but vital backbone. Its consistency, ease of use, and strong safety profile help researchers achieve more, faster and with greater confidence. A little more scrutiny, a tighter spec, or a better training session goes a long way. It pays off not just in numbers but in the stories of discovery taking shape every day. Those choices, big and small, help define what’s possible for the future of science.
