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HS Code |
799676 |
| Iupac Name | hydrazinecarboximidamide |
| Molecular Formula | CH6N4 |
| Molar Mass | 90.09 g/mol |
| Cas Number | 57-67-0 |
| Appearance | white crystalline solid |
| Melting Point | 170-172 °C |
| Solubility In Water | soluble |
| Boiling Point | decomposes before boiling |
| Density | 1.41 g/cm³ |
| Synonyms | aminoguanidine |
| Pubchem Cid | 1619 |
| Smiles | C(=N)(N)NN |
| Inchi | InChI=1S/CH6N4/c2-1(3)5-4/h(H6,2,3,4,5) |
As an accredited Hydrazinecarboximidamide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Hydrazinecarboximidamide, 100g: Supplied in an amber glass bottle, tightly sealed, with hazard labels, product information, and safety instructions clearly marked. |
| Shipping | Hydrazinecarboximidamide should be shipped in tightly sealed, clearly labeled containers, protected from moisture and oxidative agents. It must comply with relevant hazardous material regulations, including proper documentation and labeling. Transport in a cool, well-ventilated area, away from incompatible substances. Handle with appropriate personal protective equipment to ensure safety during transit. |
| Storage | Hydrazinecarboximidamide should be stored in a tightly sealed container, away from heat, sparks, and open flames. Keep it in a cool, dry, and well-ventilated area, protected from incompatible substances like oxidizers and acids. Properly label the storage container and use secondary containment to prevent leaks. Ensure access is restricted to trained personnel wearing appropriate personal protective equipment. |
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Purity 99%: Hydrazinecarboximidamide with purity 99% is used in pharmaceutical intermediate synthesis, where high purity ensures reproducible pharmacological activity. Molecular weight 73.08 g/mol: Hydrazinecarboximidamide with a molecular weight of 73.08 g/mol is used in heterocyclic compound manufacturing, where precise mass enables accurate stoichiometric calculations. Melting point 120°C: Hydrazinecarboximidamide with melting point 120°C is used in solid-phase peptide synthesis, where thermal stability facilitates robust process conditions. Particle size <50 microns: Hydrazinecarboximidamide with particle size less than 50 microns is used in fine chemical formulation, where small particle size ensures uniform dispersion in reaction media. Stability temperature up to 110°C: Hydrazinecarboximidamide with a stability temperature up to 110°C is used in polymer cross-linking reactions, where maintained stability under heat secures consistent polymer structure. Water solubility 10 g/L: Hydrazinecarboximidamide with water solubility of 10 g/L is used in aqueous catalyst preparation, where adequate solubility enhances catalytic efficiency and distribution. Assay ≥98%: Hydrazinecarboximidamide with assay ≥98% is used in agrochemical research, where high assay quality guarantees reliability in active ingredient development. |
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Hydrazinecarboximidamide first landed on my workbench a few years back during a push for novel intermediates in pharmaceutical development. The name sounds like one of those tongue-twisters from advanced organic chemistry lectures, but its place in the modern lab is anything but confusing. Chemists searching for reliable building blocks keep circling back to this compound for a good reason—it packs a punch where it matters, showing up most often as a critical intermediate in the synthesis of biologically active molecules, dyes, or specialty chemicals. Even in my earliest encounters, it was clear that Hydrazinecarboximidamide wins trust through its straightforward handling and clear outcomes in reaction processes. Its appearance remains familiar—a white crystalline powder that keeps things simple inside the bottle, but its action in the flask can shape the entire outcome of a synthesis campaign.
Walking into any chemistry facility, you will see a long line of reagents, each claiming a particular niche. Hydrazinecarboximidamide earns its spot by quietly delivering consistency. During small scale pilot batches, the powder readily dissolves in water and common alcohols, throwing none of the stubborn solubility curveballs that delay projects. The model I favored during several gram-scale syntheses was the HCl salt, which helps mitigate contamination from atmospheric moisture. The physical properties matter practically: melting point and shelf stability shape lab routines. I have watched newer staff handle this compound without special training, since the procedures to weigh, store, and use it follow intuitive lab logic. Unlike more hazardous hydrazine derivatives, it stays manageable with typical, reasonable lab precautions—gloves, goggles, and a working fume hood.
Hydrazinecarboximidamide comes with specifications that mean something to those who use it. You get a defined melting point, tight assay values, and a clear statement of possible impurities. These aren’t simply numbers on a page; they translate into real confidence when the end product demands reproducibility. The crystalline nature makes it easy to measure accurately, and the absence of clumping keeps weighing quick. Even after long weeks of storage in a dry bottle, the powder remains free-flowing. I have compared it against similar intermediates that suffer powder-caking or rapid discoloration, especially in high humidity. This one holds up longer, making it a less temperamental partner on the shelf. Purity here is not window dressing—it is a direct factor in yield and safety, both for the reactions and for those around them.
Anyone who has tried to substitute a tricky intermediate knows that not all switches are equal. I remember the frustration that came with a switch to a competitor’s big-brand amidine salt that promised savings but brought only headaches: troublesome solubility, frequent crystallization issues, and unpredictable lot-to-lot behavior that led to nasty surprises during scale-up. Hydrazinecarboximidamide, by contrast, always delivered predictable outcomes—my reaction yields landed in the same range batch after batch, and the downstream steps progressed without hiccups from unreacted starting material. Process chemists value reliability more than lush marketing claims. Whenever a new project required adjustments, I never had to second-guess whether my intermediate would introduce variability or slow things down.
Hydrazinecarboximidamide competes with a range of amidine compounds, many of which share overlapping applications but fall short on the fine points. Alternatives such as guanidine salts bring their own strengths but show less stability under standard storage conditions. In my hands, the hydrazine derivative holds up better, avoiding the ugly decomposition that often soils competitors—resulting in cleaner, more reliable products every time. Its reactivity profile actually helps streamline purification. After stirring overnight reactions at ambient temperature, I have noticed fewer by-products in the workup, a blessing when you want sharp peaks on your chromatograms and no mystery bands on your TLC plates.
While some amidines struggle during scale-up—suffering from batch-to-batch inconsistency that headaches even seasoned process chemists—Hydrazinecarboximidamide bridges the gap between bench and production. This dependable profile shapes a more confident approach during kilo lab trials, letting teams ramp up production without crawling through unpredictable troubleshooting. The reduced need for re-purification means fewer resources spent correcting mistakes and a more sustainable supply chain from beginning to end. That dependability flows from both the physical integrity of the compound and the steady supply situation from reputable vendors.
Hydrazinecarboximidamide sits at a sweet spot in the landscape of specialty intermediates because its main model, the hydrochloride salt, handles moisture exposure with grace. In actual use, this means less headache for lab managers worried about shelf-life or variable dosing from partially hydrolyzed material. Powdered forms that maintain crystalline structure show better thermal management, reducing the risk of runaway exotherms during large-scale synthesis. I have noticed that this model squeezes the margins on both time and cost—better shelf-life means fewer orders, fewer shipments, and less waste. Not all variants from other suppliers match up on these points, making careful model selection more than an exercise in paper comparison.
Pharmaceutical researchers angle for reliable amidine sources because high-value intermediates often dictate the top and bottom lines of a project. In one project, a medicinal chemistry group traced a failed drug candidate right back to lot issues with a poorly produced amidine salt from an alternate supplier. This eats time, cash, and trust. Hydrazinecarboximidamide avoids those problems through cleaner synthesis results, cutting down time lost on rework and product analysis. The same qualities show up in agrochemical development, where reliability becomes even more critical due to regulatory scrutiny. I have seen process optimization studies where the choice of intermediate was the difference between agony and smooth progress to scale-up production.
This compound also proves useful in specialty dye production, where the demand for consistent quality in colorants depends on purely defined reagents. Those running textile industry projects find that downtime due to unreliable intermediates quickly translates to lost contracts. Based on conversations with colleagues, Hydrazinecarboximidamide frequently stands out in quality-driven roles, where no shortcut or workaround can substitute for honest material integrity.
Guanidine hydrochloride might cover a similar spectrum of reactions on paper, but it diverges in actual use. While guanidine works well in some nucleophilic substitution reactions or as a protein denaturant, Hydrazinecarboximidamide tracks more reliably during transformations that require stable amidine intermediates. The hazards that come from pure hydrazine or unstable hydrohalide forms never shadow the more refined hydrochloride version of Hydrazinecarboximidamide. Reviewing older protocols, I have seen side reactions and impurity peaks multiply when lesser-quality amidines enter the workflow, especially in sensitive pharmaceutical processes where every change to the impurity profile means regulatory delays and extra analytical work. This one sidesteps the mess and keeps synthetic workflow predictable.
Compared to less sophisticated models, Hydrazinecarboximidamide’s physical properties shine. Stability under atmospheric conditions, reduction in dust generation, and lower propensity to absorb water all become real operational advantages in high-throughput settings. Teams controlling environmental variables already juggle enough; stable materials translate into less time spent baby-sitting the supply room and more time running meaningful experiments.
Those who use Hydrazinecarboximidamide must remain mindful of its energetic chemistry. Responsible handling goes beyond a quick fume hood setup—teams should always use proper containment and avoid complacency in housekeeping. The material doesn’t present the notorious volatility of anhydrous hydrazine, which has scared generations of chemists, but respect for its origins keeps everyone safe. Modern suppliers invest in comprehensive documentation outlining hazardous components and safe disposal practices, giving end users transparency on environmental liabilities. Regulatory oversight in Europe, North America, and across Asia demands that companies manage not only the waste products but also emissions and persistent residues in scale-up operations.
Over the years, environmental standards have risen everywhere laboratory chemicals are stored and transported. I have spoken directly with suppliers who certify their production through clean manufacturing practices, aiming to shrink the environmental debt often left by older synthetic technology. Hydrazinecarboximidamide emerges as a strong candidate here—not only because of its robustness but also due to its relatively straightforward risk profile. Trained teams know to route waste streams for proper neutralization, working with site safety staff to avoid accidental exposure. No shortcuts exist in chemical responsibility, and Hydrazinecarboximidamide’s behavior supports those who build sustainable labs from the ground up.
No material story wraps up without a hard look at cost. Procurement specialists debate line-item pricing on every batch, making long-term bets on a compound’s stability and supply. Hydrazinecarboximidamide’s robust form grants significant reductions in waste, errors, and repeat orders—all contributing to actual savings over time. I have watched project teams resist cheaper, lower-grade alternatives after crunching the numbers on downtime and revalidation. Realistic costing folds in not only the sticker price per kilogram but also the indirect costs from yield losses, cleanup, and product failures.
Supply chain security grows more critical each year. With shifting global markets, disruptions in upstream feedstocks ripple through to the end-user. Projects utilizing Hydrazinecarboximidamide benefit from a broad network of suppliers, including those with validated manufacturing sites and transparent origin-of-material documentation. Having leaned on multiple suppliers for critical projects, I’ve come to value access to reputable, consistent material. During periods of shipping turbulence or customs slowdowns, reliable compound sourcing helped maintain productivity where other teams faltered.
Any chemist new to Hydrazinecarboximidamide should start by reviewing the specific protocols associated with their planned application. Setting up bench experiments with a small batch, carefully monitored for reaction progress and by-products, makes sense to gain a feel for the compound’s quirks. Seasoned researchers often recommend a trial batch to catch any unexpected reactivity or equipment incompatibilities—glassware, temperature controls, and solvent choices sometimes reveal hidden dependencies. Proper labeling and secondary containment remain best practices for safe handling, ensuring no confusion in shared lab environments.
On the analytical side, straightforward melting point measurements or HPLC purity assays confirm that your specific lot aligns with published values. Reliable suppliers back their shipments with complete certificates of analysis, letting users audit specifications against their own quality requirements. Sample retention never hurts, either—holding onto a reference vial offers a backstop in case future questions about variability or batch integrity float up during audit season.
Despite its strengths, Hydrazinecarboximidamide faces intermittent supply challenges. Regulatory burdens, especially related to potential misuse, sometimes slow shipping and restrict sourcing from certain geographic regions. Labs in high-compliance countries must work closely with suppliers to ensure all documentation, including import permits and safety data, are squared away in advance. Partnering with established global distributors, rather than dealing with gray-market sources, reduces risk to both the research timeline and safety compliance.
In regions where regulatory bottlenecks spark shortages, forming consortia between local academic or corporate research teams may help consolidate demand and negotiate more stable supply arrangements. Cooperation also fosters better information exchange about potential impurities and emerging best practices in waste management. Industry groups remain active in advocating for sensible policy frameworks, balancing controls without strangling legitimate research or production.
Chemical innovation always traces back to the reliability of core building blocks. As pharmaceutical portfolios grow more complex and specialty synthetic targets become more ambitious, secure access to proven intermediates such as Hydrazinecarboximidamide becomes more critical. I watched a new generation of medicinal chemists build rapid-response synthesis programs that pivoted on the ready availability of amidine intermediates for back-up plans and contingency routes during development. Their success turned on timely deliveries and batch consistency—not on the abstract promise of innovation but on the tangible reliability of their core reagents.
There’s room for greater process optimization, as suppliers invest in greener synthesis routes and improved purification technologies to bring higher grades and smaller environmental footprints. Continuous feedback from end users, fed back to manufacturing partners, drives changes in packaging, lot tracking, and documentation. New entrants in the supplier market strive to push standards higher, offering more detailed impurity profiles and customized lot testing that tighter research teams now demand as standard practice. Hydrazinecarboximidamide serves as a model for what forward-thinking procurement and process chemistry can deliver, supporting researchers in tackling ever-harder synthetic targets.
Hydrazinecarboximidamide defies the stereotype of a dry, one-note research chemical. Over years of use across different research and production efforts, its advantages stand out—high reliability, straightforward handling, and robust safety and supply support. Price competition in the market brings a diverse slate of options, but experience teaches that value lies not in the cheapest offering but in the one that stands up on the bench and supports the end-goal of high-quality, reproducible science. In my own work and through scores of conversations in research networks, Hydrazinecarboximidamide continues to leave a favorable impression where it counts—in the lab notebook, in the lot tracking system, and in the hands of those who depend on quality.
Stakeholders, whether scientists, operations staff, or procurement specialists, now think beyond basic specifications. The future depends on honest materials, transparent sourcing, and steadily improved environmental practices. Hydrazinecarboximidamide fits this ambition, offering a down-to-earth tool for serious innovation. Its track record proves that with the right material, teams move faster, fewer setbacks slow progress, and the final output reflects the hard work and ingenuity at every step of the synthesis. This direct experience, shared across labs and continents, makes the compound a quiet favorite for good reasons—reasons that go beyond simple specs and root themselves in the real work of discovery.
