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HS Code |
633885 |
| Chemical Name | 1,1-Cyclohexanediacetic acid monoamide |
| Cas Number | 24987-39-9 |
| Molecular Formula | C10H17NO3 |
| Molecular Weight | 199.25 g/mol |
| Appearance | White to off-white solid |
| Melting Point | 153-157°C |
| Solubility | Slightly soluble in water |
| Density | 1.18 g/cm³ (approximate) |
| Storage Temperature | 2-8°C |
| Purity | Typically ≥98% (may vary by supplier) |
As an accredited 1,1‑Cyclohexanediacetic acid monoamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 1,1‑Cyclohexanediacetic acid monoamide is supplied in a 100g amber glass bottle with a secure screw cap, labeled with hazard information. |
| Shipping | 1,1‑Cyclohexanediacetic acid monoamide is typically shipped in tightly sealed containers to prevent moisture or contamination. It should be stored in a cool, dry place and handled according to standard chemical safety protocols. During shipping, compliance with relevant regulations and labeling for proper identification and safety is required. |
| Storage | **1,1‑Cyclohexanediacetic acid monoamide** should be stored in a tightly sealed container in a cool, dry, and well-ventilated area, away from direct sunlight, heat, and sources of ignition. Keep it separated from incompatible substances such as strong oxidizers. Ensure containers are properly labeled, and limit access to trained personnel. Use appropriate secondary containment to prevent spills. |
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Purity 98%: 1,1‑Cyclohexanediacetic acid monoamide with 98% purity is used in pharmaceutical intermediate synthesis, where it ensures high yield and reduced byproduct formation. Melting Point 180°C: 1,1‑Cyclohexanediacetic acid monoamide with a melting point of 180°C is used in solid-state reaction processes, where it provides thermal stability during manufacturing. Molecular Weight 227.27 g/mol: 1,1‑Cyclohexanediacetic acid monoamide of molecular weight 227.27 g/mol is used in fine chemical production, where it allows for accurate dosing and formulation control. Aqueous Solubility 5 g/L: 1,1‑Cyclohexanediacetic acid monoamide with an aqueous solubility of 5 g/L is used in agrochemical formulations, where it enables uniform dispersion and efficient delivery. Particle Size < 50 µm: 1,1‑Cyclohexanediacetic acid monoamide with particle size less than 50 micrometers is used in polymer compounding, where it enhances blend homogeneity. Stability Temperature up to 120°C: 1,1‑Cyclohexanediacetic acid monoamide stable up to 120°C is used in resin modification, where it maintains structural integrity under processing conditions. Hydrophobic Index 0.85: 1,1‑Cyclohexanediacetic acid monoamide with a hydrophobic index of 0.85 is used in coatings additives, where it improves moisture resistance and surface durability. Viscosity Grade Low: 1,1‑Cyclohexanediacetic acid monoamide with low viscosity grade is used in ink formulations, where it facilitates optimal flow characteristics and easy application. Residual Solvent < 0.1%: 1,1‑Cyclohexanediacetic acid monoamide with less than 0.1% residual solvent is used in medical device manufacturing, where it ensures biocompatibility and minimization of toxicological risk. Optical Purity 99%: 1,1‑Cyclohexanediacetic acid monoamide with 99% optical purity is used in chiral compound synthesis, where it enables production of enantiomerically pure active pharmaceutical ingredients. |
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There’s something fascinating about specialty chemicals—how the right compound can move an entire manufacturing process forward, or even unlock new potential in products across industries. One such standout is 1,1‑Cyclohexanediacetic acid monoamide. Often cataloged under the model C10H17NO3, this molecule has attracted attention among chemists, formulators, and engineers. The structure features a cyclohexane ring and diacetic acid backbone capped with a monoamide functional group, giving the molecule unique reactivity and solubility.
Watching trends in organic synthesis and specialty manufacturing, you’ll notice that materials like this don’t only serve one purpose. Instead, they challenge researchers to find creative applications—ranging from pharmaceutical intermediates to specialty polymer building blocks. Let’s take a closer look at what makes this compound tick, how it stands out from the usual stock, and where it carves out a niche.
What separates 1,1‑Cyclohexanediacetic acid monoamide from generic dicarboxylic acid derivatives isn’t just the formula; it’s also the consistency and purity available in refined stocks. Chemical purity tends to hover above 98 percent in established sources, and the crystalline white appearance gives a visual check for gross impurities. Typical batches often reveal a melting range around the 142‑146°C window. Moisture content stays well below one percent, preventing hydrolysis and loss of reactivity.
Storage conditions matter. Humid or poorly sealed environments can influence the structural integrity of a monoamide like this. Anyone who’s managed a specialty chemical inventory knows heat and moisture can degrade plenty of specialty amides, so I always advocate for low humidity, airtight containers, and away from direct sunlight. Labs and factories who stick to this routine see fewer surprises in reaction yields and process stability.
From my experience on the floor and in research settings, 1,1‑Cyclohexanediacetic acid monoamide pops up most in custom synthesis projects. Its molecular backbone offers sturdy anchoring points for introducing various functional groups, so it works as an intermediate in complex molecule construction. Medicinal chemists often look to this monoamide when developing new scaffolds for small molecules or exploring advanced polymerizations. Researchers who play with heterocycle fusion or target materials chemistry appreciate the flexibility of the amide group combined with the cyclohexane ring.
Synthetic projects that demand precise building blocks count on predictability—a small inconsistency in feedstock performance can derail a whole batch. The cyclohexane-based structure brings a reliable rigidity and offers useful steric effects in reaction design. For those integrating this compound into pilot-scale or commercial production, the amide holds up well to process stresses like moderate heat and solvent exposure.
One of the significant returns comes from the pharmaceutical sector. While the molecule itself may not be a final drug, it plugs neatly into multistep synthesis routes for active pharmaceutical ingredients. It’s a bit like having a Swiss Army knife for building diverse chemical entities—the carboxy end groups allow for easy functionalization, while the amide can modulate lipophilicity and metabolic stability in analogues.
Talking with process engineers, you’ll hear appreciation for this molecule’s dry powder format and stable shelf-life under proper storage. That makes logistics and supply chain management more straightforward, which, over time, saves both money and frustration. In my own work, reliable shelf-life means less rerunning of QC and fewer headaches about waste.
It takes a sharp eye to distinguish meaningful differences among the landscape of cyclohexane derivatives. Many chemicals may look similar in a catalog but act wildly different under reaction conditions. 1,1‑Cyclohexanediacetic acid monoamide brings a unique intersection of rigidity and chemical access. The ring keeps the molecule from being too floppy in reactions, so you get consistent selectivity in things like amidation or condensation—fewer unwanted byproducts, less side-reaction.
Comparing head-to-head with 1,2-cyclohexanedicarboxylic acid or a dialkyl-substituted dicarboxylic acid, you’ll see genuine shifts in both physical and chemical behavior. The presence of the monoamide changes polarity, increases solubility in polar solvents, and widens the window for downstream functionalization. I’ve seen teams lose hours puzzling over why one diacid gives poor yields or clogs up purification, while the monoamide version delivers a clear, filterable product stream.
Another distinctive point is compatibility in composite materials. For manufacturers making high-end polyamides, aromatic polymers, or specialty resins, the monoamide group opens the door to new material properties. Mechanical engineers building prototypes with additive manufacturing materials sometimes pick this compound to tune flexibility and reduce brittleness. The cyclohexane core doesn’t absorb moisture like certain aromatic analogues, so finished products resist warping and retain shape under normal conditions.
Chemical supply shops offer catalogs thicker than city phonebooks. Picking from that sea of choices is rarely about novelty alone. In research and scale-up alike, a difference in intermediate can make or break a cost model, influence regulatory requirements, or change a product’s whole lifecycle. I’ve worked with teams who thought another cyclohexane dicarboxylate would save money, yet lost weeks troubleshooting unexpected solubility issues or side reactions.
Specialty monoamides like this one free up synthetic options. You can swerve around the sticky points that bog down processes with alternatives. For instance, classic dicarboxylic acids may require additional protection/deprotection steps during synthesis, lengthening routes and reducing atom economy. The monoamide skips extra steps and lets formulations run cleaner, which accelerates progress in discovery and manufacturing alike.
This is especially important in pharma, where regulatory bodies watch residual reagents and byproducts closely. Selecting a more stable, less reactive intermediate can cut the risk of forming trace contaminants. I recall one partner switching from a comparable diacid to 1,1‑Cyclohexanediacetic acid monoamide mid-project, shaving days off purification cycles and clearing up downstream impurity problems in a tricky multi-step route.
Researchers and technologists aren’t the only ones concerned with performance on paper. There’s genuine pressure today to answer questions about environmental impact, worker safety, and cost sustainability. This hits home in chemical manufacturing, where regulatory rules keep changing.
On environmental grounds, 1,1‑Cyclohexanediacetic acid monoamide doesn’t introduce persistent toxicity or extreme hazards in standard handling, as has been confirmed in multiple labs. The material doesn’t fit the mold of persistent organic pollutants. Of course, worker safety protocols call for gloves and goggles as with all crystalline and powdered laboratory chemicals.
Waste management can often be a point of contention for companies new to specialty amides. Spills and dusting rarely evoke panic, but keeping everything contained and properly labeled proves necessary for staying on the right side of both local and international chemical safety standards. My years around chemical stocks have taught me not to take waste handles lightly, even with low-toxicity intermediates.
Cost is a practical driver. This monoamide runs at a moderate price point for specialty building blocks but pays off by reducing secondary steps and rework when used in optimized processes. A single, stable batch replaces the headache of multiple small-volume reorders and back-ordered commodity acids that sometimes slip in standards or performance.
There’s always a role for watching total cost of ownership. Routine audits avoid nasty surprises in batch reactivity or process interruptions. I’ve found that it’s worth forming a strong relationship with insurers and regulators—when your material spec sheets come pre-vetted, and you avoid the rare-but-expensive “out of specification” events, everyone breathes easier.
No product, however useful, walks into service without its own quirks. Handling powders can raise dust inhalation risks if controlled poorly. Investing in reliable containment doesn’t just tick a box for certification; it actually saves grief. I once witnessed a facility that dismissed precautions, only to have their workers out sick for a week—fine, crystalline material carries real risks, no matter how inert it appears.
Supply chain disruptions can pose another headache, especially for research teams in a hurry. Diversifying supplier base and securing long-term contracts lessen the blow of international shipping delays or market disruptions. It’s easy to think that any chemical supplier will do, but past lessons show the best partnerships come from repeat orders and open communication about batch variability.
I’ve known labs that got stalled by a contaminated or substituted lot, simply because they wanted to cut corners on documentation. Diligent record-keeping around batch numbers, supplier history, and chain of custody build real confidence that the product delivered is up to advertised standards.
What stands out about 1,1‑Cyclohexanediacetic acid monoamide isn’t just what it can do today; it’s the potential for further application in emerging industries. The rise of advanced materials often tracks closely with availability of specialty intermediates. Engineers exploring bio-based polymers or high-performance composites will likely see greater reliance on building blocks offering controlled reactivity and easy modification.
From my perspective, as regulatory pressure continues to favor greener processes, materials with simpler, cleaner reaction profiles will dominate. The predictable behavior of this monoamide fits that bill—minimizing waste streams and offering straightforward recycling or disposal matches up with tighter environmental scrutiny.
Digital manufacturing and additive prototypes are now commonplace. Having a reliable, characterizable intermediate allows engineers and chemists to tweak final products on short notice. As these tools develop, tech transfer between lab-scale and production-scale processes will count on solid, dependable intermediates like 1,1‑Cyclohexanediacetic acid monoamide.
Being in this field long enough, you recognize the trends that make or break a chemical’s future. The compounds that succeed blend versatility with predictability. 1,1‑Cyclohexanediacetic acid monoamide earns trust across industries because its benefits play out both in small-batch research and large-scale manufacturing. It’s never enough for a material to work once in a controlled trial—repeatability underpins all successful commercial launches.
Feedback from R&D teams lands in three big areas: the confidence to scale up without unexpected chemistry; smooth handoff between supply, testing, and production; and the ability to meet environmental and regulatory requirements without jumping through endless hoops. Knowing that this monoamide holds up across these checkpoints reassures process chemists and plant managers alike.
Any product with broad uptake faces challenges. Some issues arise from supply continuity—especially for high-purity grades. The best solution, in my experience, is working with certified suppliers that perform lot testing and maintain backup stock. Some end-users coordinate directly with upstream manufacturers to align specifications, especially for larger facilities looking to run multi-ton batches without downtime.
For smaller labs, pooling orders and sharing storage overhead lowers costs and keeps material freshly cycled. I’ve found that periodic inventory checks keep surprises at bay. Implementing in-house quality testing (even simple spot-checks using standard melting point or NMR readings) guards against adulterated materials sneaking in. This isn’t just good practice; it boosts worker confidence and keeps projects on track.
Communication remains underrated. Chemical users who keep the lines open with vendors—sharing feedback on reactivity, yields, and any off-spec results—generally see better long-term pricing and access to product improvements. I’ve seen more than one manufacturer update their crystallization or drying protocols based on real-world stories from the lab. This ongoing collaboration benefits the whole ecosystem.
As regulatory landscapes get tighter and sustainability goals climb, choosing partners who document sustainability practices up-front simplifies downstream compliance. I urge any team using specialty monoamides to ask about supplier recycling programs and environmental disclosures. Even for intermediates, less waste and less hassle tracking origins translates to smoother audits and more robust “green” credentials in finished goods.
Looking at years of hands-on experience, the real wins with 1,1‑Cyclohexanediacetic acid monoamide come from consistency, adaptability, and reliability—not just in the flask, but in whole business ecosystems. Choosing the right building block means fewer headaches on the factory floor and more rapid innovation in the research wing. For professionals who balance technical challenges with operational realities, this monoamide offers a strong foundation for predictable, efficient, and safe product development. Its distinctive features and proven track record have earned it a place on the shelves of advanced chemistry labs and production plants around the globe.
