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HS Code |
434024 |
| Cas Number | 3614-85-9 |
| Molecular Formula | CH3NO·HCl |
| Molecular Weight | 81.50 g/mol |
| Iupac Name | Formaldoxime hydrochloride |
| Appearance | White to off-white crystalline powder |
| Melting Point | 133-135 °C |
| Solubility In Water | Soluble |
| Storage Temperature | 2-8 °C |
| Synonyms | Methanal oxime hydrochloride |
| Pubchem Id | 33575 |
As an accredited Formaldoxime Hydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Formaldoxime Hydrochloride is packaged in a 25g amber glass bottle, tightly sealed, labeled with hazard symbols, and product details. |
| Shipping | Formaldoxime Hydrochloride should be shipped in tightly sealed containers, protected from moisture and light. Transport in accordance with local, national, and international regulations for hazardous chemicals. Ensure labeling as a corrosive and irritant material. Handle with caution using appropriate safety equipment to prevent exposure to skin or eyes during shipping and delivery. |
| Storage | Formaldoxime Hydrochloride should be stored in a tightly sealed container, in a cool, dry, and well-ventilated area away from direct sunlight, moisture, and incompatible substances such as strong oxidizers and bases. It should be kept at room temperature and protected from physical damage. Proper labeling and secure storage are essential to prevent accidental exposure and ensure chemical stability. |
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Purity 98%: Formaldoxime Hydrochloride with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high conversion efficiency and product yield. Melting Point 151°C: Formaldoxime Hydrochloride at melting point 151°C is used in fine chemical manufacturing, where it allows for controlled processing conditions and enhanced product stability. Molecular Weight 85.52 g/mol: Formaldoxime Hydrochloride with molecular weight 85.52 g/mol is used in laboratory reagent preparation, where it provides accurate calculations and reproducible results. Stability Temperature 25°C: Formaldoxime Hydrochloride with stability temperature 25°C is used in storage and transportation applications, where it maintains chemical integrity and prevents degradation. Water Solubility 100 g/L: Formaldoxime Hydrochloride with water solubility 100 g/L is used in aqueous reaction systems, where it offers rapid dissolution and homogeneous mixing. Appearance White Crystalline Powder: Formaldoxime Hydrochloride with appearance as white crystalline powder is used in analytical chemistry, where it enables easy handling and precise weighing. pH Stability Range 4-8: Formaldoxime Hydrochloride with pH stability range 4-8 is used in buffer solution formulations, where it ensures consistent reactivity and prolonged shelf life. |
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For those who spend hours in labs or production facilities, precise outcomes don’t come from luck. Chemicals like Formaldoxime Hydrochloride, model C2H6ClNO, play a bigger role than many realize. This powder, usually white or off-white, doesn’t attract much attention, but its presence shapes the quality of syntheses and research across pharmaceuticals and specialty manufacturing. While chemistry textbooks and sales catalogs toss around plenty of technical data, day-to-day experiences in the field reveal both the true strengths and quirks of Formaldoxime Hydrochloride.
Labs relying on rigorous methods and reproducible results often use Formaldoxime Hydrochloride as a reagent for identifying aldehydes and ketones or for transforming carbonyl groups into oximes. The hydrochloric salt increases its water solubility and keeps handling straightforward, helping technicians reach higher purity yields without resorting to complicated solvent tricks or lengthy purifications. Anyone who’s spent an afternoon watching stubborn precipitates refuse to form will appreciate how this compound can turn a challenging purification into a routine filtration. The hydrochloride form also reduces the pungent odor found in the free base, which improves lab safety and comfort.
Users often expect assay concentrations above 98% to make sophisticated syntheses work efficiently. Detail-oriented labs pay attention to melting point ranges—usually around 151-155°C for Formaldoxime Hydrochloride—because small variations can signal impurities that later undermine sensitive reactions. Water content and chloride content matter, too. Too much water or excessive chloride shifts stoichiometry and can spark side-reactions or waste time cleaning up unwanted byproducts. Rather than packing in excess description, it makes more sense to trust reputable sources and regularly test batches rather than take anyone’s word at face value.
Modern pharmaceutical development stands on the shoulders of reagents like this. In some reactions, Formaldoxime Hydrochloride takes on the heavy lifting in building heterocyclic cores or serving in intermediates for anti-infective drugs. A well-curated supply saves weeks in trial-and-error. Few things slow down drug discovery more than inconsistency in core reagents. By sticking to batches meeting tight purity boundaries, research groups dodge setbacks that drain both time and grant funding. Years of bench experience underscore that small investments upfront pay for themselves many times over when scaling up to pilot runs or first-in-human studies.
Saying that industry "requires tight quality control" sounds like a platitude. Reality cuts through marketing talk. One contaminated drum can trigger recall protocols or even halt an entire process line. Labs that monitor incoming Formaldoxime Hydrochloride with HPLC and NMR lead the way on traceability. Documentation tells part of the story, but running the compound through real operational conditions in the actual end-use step shows how it behaves under stress. Scientists share stories about deteriorated batches that looked fine on paper but produced inconsistent final products, teaching everyone in the room a valuable lesson about complacency.
Suppliers often claim their product blends seamlessly, dissolves quickly, and stores safely. From direct experience with Formaldoxime Hydrochloride, storage in airtight, light-protected containers reduces degradation and clumping. Repeated opening can let in enough moisture to trigger slow hydrolysis, changing the performance over time. Respecting these physical limitations makes a real difference between a batch that kicks off a flawless reaction and a disappointment that wastes an afternoon.
Each laboratory discipline seems to claim their oxime of choice: some swear by Methoxylamine, others by Hydroxylamine Hydrochloride. Formaldoxime Hydrochloride separates itself by combining stability with reliable reactivity. Hydroxylamine variants, while cheap, often come with more safety baggage and can be less predictable in some organic syntheses. Methoxylamine gets involved in some mild reactions, but the hydrochloride form of Formaldoxime hits a nice balance between shelf life and functional group selectivity. No universal winner exists, but for chemists making oximes from aldehydes, this compound stands out.
Small issues snowball fast in busy teaching laboratories or high-throughput screening units. Poorly labeled containers, inconsistent particle size, or mismatched lot documentation routinely slow workflows. A batch of Formaldoxime Hydrochloride that doesn’t match the stated melting point or that releases strong odors suggests poor processing or aging. Anyone managing inventory for university labs will confirm that disciplined labeling, prompt rotation, and clear supplier communication keep even the most routine chemical from turning into tomorrow’s headache. Those tasked with purchasing or using Formaldoxime Hydrochloride benefit most when they approach every delivery with skepticism and back up claims with quick on-site verifications.
SDS documents and safety guidelines make chemical handling look neat and tidy. But real-life lab benches are cluttered places where spills and unexpected exposures occur—especially during long hours or training new staff. In my experience, Formaldoxime Hydrochloride’s relative low toxicity shouldn’t tempt anyone to treat it lightly. Even compounds with modest data profiles can trigger skin or respiratory irritation. Good gloves, a decent fume hood, and regular surface cleanings make risky exposures a remote event. Veteran lab managers pass down practical lessons—wipe down balances daily, double-bag after opening, and watch for subtle discoloration that flags aging—these tips outlast procedure manuals that gather dust on the shelf.
Beyond its function as a reagent, this compound enables careful analysts to detect low-level aldehydes in environmental samples, food, and industrial feedstocks. Testing for trace formaldehyde or acetaldehyde in water and air gets a helping hand from its unique chemical affinity. Sample prep can make or break an analysis run, and this is where Formaldoxime Hydrochloride often steps in as a derivatizing agent, forming stable oximes that GC or HPLC instruments can quantify with precision. Researchers hunting for reliable, cost-effective analytical reagents favour it for its performance and ease of clean-up. Overworked analysts can trust repeatable results, cutting down on time spent chasing false positives or rerunning failed tests.
Anyone who’s bought specialty chemicals for years realizes that catalog promises and real-world batches sometimes diverge. Department heads buying Formaldoxime Hydrochloride for entire teams or even for just a few major projects often negotiate direct with suppliers for COA documentation and batch reserve samples. Testing new batches against known “in-house controls” prevents surprising failures. Some even favor splitting orders between two sources, so a last-minute shipment problem doesn’t cripple their timeline. Wise procurement rests on both tested trust and a healthy amount of verification.
Careless storage erodes product integrity faster than most realize. Regular checks on container seals, moisture absorbers, and clear labeling can double the usable life of Formaldoxime Hydrochloride. In humid climates, dedicated dry cabinets or desiccator jars add another layer of insurance. Disposal brings another round of challenges. Dumping reagents down a laboratory sink is both dangerous and illegal. Labs following local and international waste guidelines avoid headaches with regulators and protect the health of janitorial staff and the broader environment. Smart managers coordinate with certified waste contractors, document every gram disposed, and train new team members to do the same from their first day.
Most chemical mishaps trace back to hurried communication or overlooked changes. Even in routine contract manufacturing runs, missing a minor update—like a tweak in Formaldoxime Hydrochloride particle size—can disrupt equipment calibration and waste batches. Cross-checking incoming material for both analytical and physical consistency shows respect for downstream users and reduces the need for awkward troubleshooting meetings under project deadlines. Teaching new staff to check, re-check, and communicate even trivial-looking changes weaves reliability into a team’s daily rhythm.
Regulations continue to evolve, especially as governments react to new research on chemical toxicity or environmental harms. Chemicals like Formaldoxime Hydrochloride, which haven’t come under intense public scrutiny yet, still benefit from being sourced and documented above-board. Teams that maintain rigorous documentation not only meet current guidelines but also future-proof themselves should regulations tighten. Using chemicals with clear, verifiable purity, traceable back to audited suppliers, gives buyers and managers a practical edge in an uncertain landscape.
Every year, labs lose time—and sometimes credibility—by leaning on incomplete product information or discounted “last-lot” deals. Rushed purchases often look tempting when budgets are tight, but these come with real risks: surprise contamination, missing documentation, or unstable batches. Veteran chemists share stories of whole project phases delayed by overlooked batch discrepancies. Learning the lesson once by having a pilot run fall apart due to a subpar lot of Formaldoxime Hydrochloride leaves a lasting impression and makes thorough vetting a lifelong habit.
In classrooms and teaching labs, chemicals walk a tightrope between safety and demonstration value. Formaldoxime Hydrochloride’s manageable hazard profile makes it suitable for intermediate-level experiments under careful supervision. Students working with real reagents learn proper weighing, dissolution, and safe disposal, building habits that last beyond their degrees. Teachers benefit from using a chemical with widely available technical literature, so they can design experiments and answer “what if” questions confidently. A routine synthesis or detection reaction using this compound often becomes the first real “Aha!” moment for budding chemists.
Raw price doesn’t always tell the whole story. Cheaper batches sometimes come with inconsistent particle size, questionable origin, or weaker technical support. Repeat buyers quickly realize that a small price premium often corresponds with responsive customer service, reliable delivery, and real support when troubleshooting issues. Values like transparency, repeatability, and accountability matter just as much as technical specs. Labs that treat Formaldoxime Hydrochloride sourcing as a relationship, not just a transaction, secure both current and future success.
As new fields—like sustainable packaging or specialty coatings—increase demand for precise organic transformations, reliable reagents remain essential. Chemical startups and academic research teams continue to find new uses for oximes and related intermediates. Even as old techniques remain stable, evolving demands call for better-tested and more transparent sourcing, further cementing the reputation of consistently produced Formaldoxime Hydrochloride.
Beyond suppliers, journals, and handbooks, the best insight comes from open forums where chemists, technicians, and students exchange stories. One startup shared how inconsistent solubility nearly derailed their initial product launch, only to resolve the issue by switching suppliers and tightening their verification protocols. Another team found that switching to Formaldoxime Hydrochloride from a competitor reagent improved their yield and product stability, ultimately convincing skeptical investors of their process’s merit. These anecdotes, candid and unfiltered, form the backbone of real-world experience that no data sheet alone can offer.
Building trustworthy lab and production environments rests on more than facts and figures. By viewing Formaldoxime Hydrochloride not just as an interchangeable commodity, but as a crucial contributor to project success, teams elevate their own standards. Asking the extra questions, checking every lot, and prioritizing strong communication ensures that the benefits of this versatile reagent don’t get lost in the shuffle. Over countless projects and years on the bench, the lesson holds true: the right chemical, used with care and understanding, always pays for itself in smooth workflows, happy teams, and successful results.
