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HS Code |
664903 |
| Chemical Name | alpha-Phenyl-2-pyridineacetonitrile |
| Cas Number | 6575-83-9 |
| Molecular Formula | C13H10N2 |
| Molecular Weight | 194.23 g/mol |
| Appearance | White to off-white solid |
| Melting Point | 90-93 °C |
| Solubility | Slightly soluble in water, soluble in organic solvents |
| Smiles | C1=CC=CC=C1C(C#N)C2=CC=CC=N2 |
| Purity | Typically >98% |
| Storage Conditions | Store at room temperature, keep container tightly closed |
| Synonyms | 2-(Phenyl(pyridin-2-yl)methyl)acetonitrile |
| Hazard Statements | May cause skin and eye irritation |
As an accredited alpha-Phenyl-2-pyridineacetonitrile factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 25g amber glass bottle with a white screw cap, labeled "alpha-Phenyl-2-pyridineacetonitrile," displaying hazard symbols and batch information. |
| Container Loading (20′ FCL) | **20′ FCL:** Securely packed 20-foot container, compliant with chemical transport standards, ensuring safe, moisture-free shipment of alpha-Phenyl-2-pyridineacetonitrile. |
| Shipping | Alpha-Phenyl-2-pyridineacetonitrile should be shipped in tightly sealed containers, clearly labeled, and protected from light, heat, and moisture. Comply with local and international transport regulations for chemicals. Use secondary containment and appropriate cushioning to prevent breakage or leaks, and supply shipping documentation specifying chemical identity and safety precautions. |
| Storage | Alpha-Phenyl-2-pyridineacetonitrile should be stored in a tightly closed, clearly labeled container, in a cool, dry, and well-ventilated area away from direct sunlight, heat, and sources of ignition. It should be kept separate from incompatible substances such as strong oxidizing agents and acids. Use appropriate secondary containment and ensure that storage complies with relevant safety and regulatory guidelines. |
| Shelf Life | Alpha-Phenyl-2-pyridineacetonitrile is stable under recommended storage conditions; shelf life is typically 2-3 years in a cool, dry place. |
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Purity 98%: alpha-Phenyl-2-pyridineacetonitrile with Purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high yield and minimized by-products. Molecular Weight 220.26 g/mol: alpha-Phenyl-2-pyridineacetonitrile with Molecular Weight 220.26 g/mol is used in custom organic synthesis, where it delivers predictable stoichiometry in coupling reactions. Melting Point 78°C: alpha-Phenyl-2-pyridineacetonitrile with Melting Point 78°C is used in solid-phase synthesis processes, where it provides controlled thermal handling and consistency. Particle Size <50 μm: alpha-Phenyl-2-pyridineacetonitrile with Particle Size <50 μm is used in catalyst formulation, where it promotes homogeneous dispersion and reactivity. Stability Temperature up to 120°C: alpha-Phenyl-2-pyridineacetonitrile with Stability Temperature up to 120°C is used in high-temperature synthetic protocols, where it maintains structural integrity and process reliability. Low Residual Solvent (<0.1%): alpha-Phenyl-2-pyridineacetonitrile with Low Residual Solvent (<0.1%) is used in sensitive pharmaceutical manufacturing, where it reduces contamination risk and meets regulatory compliance. |
Competitive alpha-Phenyl-2-pyridineacetonitrile prices that fit your budget—flexible terms and customized quotes for every order.
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Producing alpha-Phenyl-2-pyridineacetonitrile opens doors for a range of industries, particularly as demand grows for specialty intermediates in pharmaceuticals and advanced materials. In our production facility, attention settles on every subtle detail throughout synthesis, purification, and packing. The molecular structure—where a phenyl group and a nitrogen-containing pyridine ring connect via an acetonitrile linker—proves robust and versatile. Chemists appreciate the molecule’s reactivity and stability. For those of us guiding daily operations, these features drive our selection of reactants and process controls.
Years of feedback shape our go-to model for alpha-Phenyl-2-pyridineacetonitrile. Our product leaves the reactor as a fine, white to off-white solid, consistently tested above 98% purity through HPLC and GC methods. Our homage to precision traces back to customer input—no one overlooks trace impurities or expects surprises in spectra. We've found high purity to be more than a selling point; it’s central to downstream transformations where any unidentified peak can derail a whole batch synthesis.
Adhering to such strict quality standards means more than good chemistry—it requires hard-won knowhow at each stage. In our experience, careful control of the condensation and subsequent cyclization steps makes all the difference. Temperature, stirring, and solvent choice affect how the final product crystallizes out, which in turn determines how easily the product is purified during washing and drying. The wide applicability of this compound for heterocyclic chemistry means receiving plenty of development requests, and every kilogram we ship represents tangible trust from users expecting consistency.
Chemists in the lab look for ease of handling and predictable results. The crystalline nature of our alpha-Phenyl-2-pyridineacetonitrile lends itself well to careful weighing and sampling. Its modest melting point range makes it straightforward to assess purity and provides early warning of solvent residues or polymorphic changes. During scale-up, our team often revisits the filtration and drying steps, since humidity or unexpected temperature dips in the plant can subtly shift appearance. Each batch undergoes a full battery of melting point, purity, and moisture checks. Over the years, we discovered slight adjustments in anti-caking measures go a long way for customers in humid climates.
Moisture control remains a running theme. Our teams learned to double-bag the final product and rotate drying protocols after a few customer complaints about minor clumping, especially in the wet season. Listening to direct user feedback helped us refine packaging. True feedback always comes from those who open bags and scoop powders in busy pilot plants, not from any paper specification sheet.
Often, discussions pile up comparing alpha-Phenyl-2-pyridineacetonitrile with related compounds, such as its unsubstituted or methylated cousins. While each molecule offers a different twist on reactivity, we’ve seen our phenyl derivative rise in popularity for more challenging cross-coupling and cyclization reactions. The phenyl group tends to stabilize intermediates, enabling chemists to attempt bolder reaction designs. Sophisticated pharmaceutical syntheses favor this compound precisely for its mix of stability and reactivity—it stands up to heat while remaining amenable to subtle functionalization along the pyridine ring.
Other similar chemicals, like 2-pyridineacetonitrile or alpha-tolyl-2-pyridineacetonitrile, sometimes fall short in key applications. We field regular requests for advice on switching from a more basic arylacetonitrile, with the need for improved selectivity or cleaner reaction profiles. Years of in-house application testing convinced us that the alpha-Phenyl-2-pyridineacetonitrile’s electronic structure balances synthetic flexibility with the fortune of relatively mild handling properties. Its limited volatility overcomes safety hurdles often flagged with simpler nitriles.
Some clients ask why not choose cheaper arylacetonitriles. Our response always circles back to yield and downstream ease. The phenyl group actively suppresses side-reactions during metal-catalyzed coupling, and its nucleophilicity sits in a sweet spot for forming new bonds with minimal byproduct headaches. Our QC lab logged scores of comparative runs, and the data made a clear case: alpha-Phenyl-2-pyridineacetonitrile saves time and solvents in multi-step plant operations, cutting headaches for process chemists targeting gram-to-ton sales.
The majority of our customers work in R&D, scale-up, or pilot plant settings. We understand an uninterrupted supply and unchanging product behavior shape their success just as much as our own. Each year, we deal with changing regulations on solvent use and waste minimization, often anticipating questions from clients on documentation and traceability. Our standard lot sizes settle around multi-kilogram packaging, with smaller laboratory samples available on request for trialing new routes.
Many suppliers overlook the significance of sample retention and batch history records. We maintain a rolling archive of batch spectra and history sheets—old habits instilled from repeat questions on past lots, especially after customer processes evolve. Once, a client traced an unexpected impurity back to an old batch. The ability to provide matching chromatograms earned us long-term trust. In manufacturing, transparency and responsiveness outlast any marketing claim.
We value engaging directly with scientists facing unexpected results. Sometimes, a customer finds a new transformation requiring a small change, such as a different solvent system or further reduced trace contaminants. Rather than sending a generic response, our technical group partners with theirs, sharing GC and NMR traces, and advising if experimental protocols may need realigning. We believe working with the end-user as fellow problem solvers builds a relationship rooted in mutual respect, rather than transactional exchanges.
No process remains static in this space. Our operators on the production floor regularly flag changes in raw material quality, especially when global supply chains shift. Some years, we dealt with shortages in key aromatic intermediates. Our adjustment: building stronger ties with local sources and stocking above our usual buffer, so no run ever has to be canceled due to raw material bottlenecks. Operations sometimes grind down to small details—purity of acetone washes, checking the fit of filter bags, and tuning the duration of nitrogen purges.
Handling hazardous and trace volatile substances calls for real vigilance. In the heart of production, we committed resources to fresh air sampling for cyanide residues and regular operator health screens. Every shift, our workers step into well-ventilated, monitored environments with protocols built on experience instead of unchecked routines. Focusing on the people behind the chemistry keeps the operation sustainable and safe for the long haul. Only by attending to ergonomic processes do we ensure those same staff stay sharp and committed to quality.
During shipping, we use leak-proof, sealed containers and closely monitor temperature and handling routes. Especially during hotter months, shipping crews double-check packaging integrity and track real-time data on shipment conditions. The smallest oversight—a torn liner, a forklift puncture, a missed label—can put an entire project at risk for our clients. We keep extra liners, desiccants, and sealers on hand, shipping out replacements if a client anywhere catches a problem.
Regulations never stand still, especially in tight-margined chemical manufacturing. We keep a full set of compliance documents and update them whenever international or domestic authorities revise their standards for chemical handling, transport, or labeling. Over time, increasingly strict environmental directives forced us to rethink solvent choices. More of our processes now run on water-washable or recycled solvents, which we track carefully through mass-balance audits.
Emissions controls for potentially hazardous intermediates have gotten sharper. Our team invested in new capture and neutralization units to keep airborne organonitriles below legal limits. Besides avoidance of fines, this kind of infrastructure gives neighbors and staff peace of mind—no one enjoys working by the boundary fence of a plant emitting unfamiliar odors. Transparent reporting, open-door inspections, and honest engagement form our main approach to environmental stewardship.
Documentation matters more than ever. Years spent building our digital records system mean retrieving historic batch documents or delivering regulatory submissions rarely slows us down. If an agency wants to review an entire year’s output, we pull files quickly, piecing together tracking records, raw material sources, and final analyses. Staying audit-ready saves time and builds confidence for our customers, who rely on us for both material and compliance certainty.
As users push for higher purity or new application trials, we adjust our parameters. Not every process can be tweaked instantly, but our plant teams pride themselves on adapting. Sometimes, a request comes to further reduce a stubborn trace contaminant below the already tight spec. We dig into reaction parameters, adjust crystallization cooling rates, and run extra washes. It takes direct conversations between our technical teams and our clients’ chemists, trading sample spectra and work-up protocols, until the process runs clean.
We encourage open trials and pilot-scale collaboration. Whenever chemists report side reactions or rare decomposition, laboratory teams experiment to see if a temperature tweak or different base might suppress byproducts. If needed, we’ll rework a small lot under those new settings and ship samples out for feedback. Some requests have inspired us to install new analytical equipment, fortifying both our own control and our clients’ confidence in their outcomes.
The mainstay for alpha-Phenyl-2-pyridineacetonitrile usage remains as a building block in custom synthesis of pharmaceuticals, agrochemical candidates, and specialty ligands. Research groups turn to it for building advanced heterocycles and fine-tuning bioactive molecules. We have observed growing interest from electronic material developers who exploit the molecule’s pyridine core for constructing functional polymers and charge-transport agents.
From our view, customizing downstream chemistry means considering solvent compatibility, scale-up stability, and expected transformations. Process chemists regularly engage with us to troubleshoot solubility or extractability issues when developing API intermediates. Occasionally, a new downstream application highlights an impurity previously overlooked, prompting us to further refine the production route. Staying nimble on the production side keeps us relevant as new fields explore these versatile molecules.
In the research lab, rapid availability and pre-tested purity boost productivity during exploratory synthesis. In the pilot plant, robust supply lines and reliable data play just as big a role. We feel the responsibility of supporting both front-end innovation and steady commercial operations. Our attention to securing timely shipments and supporting first-time buyers has earned us continued collaboration with both emerging laboratories and established players alike.
Each year, we witness new demands for even more refined molecules, but alpha-Phenyl-2-pyridineacetonitrile continues to earn its keep because of the reliability it offers in the hands of experienced chemists. Its blend of predictable reactivity, workable handling, and accessibility lets researchers focus on the higher-level objectives—innovation, discovery, and rapid prototyping—instead of trouble-shooting ingredient variability. Meanwhile, commercial process teams demand the kind of steadfast quality that comes from real manufacturing experience, not marketing promises.
We stay in close contact with our clients, offering advice based on years spent solving real manufacturing hitches—reactor failings, supplier delays, humidity spikes, and shifts in global transport. Steady supply and technical expertise go a long way to smoothing project launches. We remain committed to supporting innovation by keeping production reliable and offering honest, direct guidance to scientists chasing the next breakthrough.
Manufacturing alpha-Phenyl-2-pyridineacetonitrile means never standing still. Each project, feedback round, or challenge teaches us something new. Our teams regularly review process logs to spot shifts in yields or reaction times. Scheduled training and open floor meetings mean every operator’s suggestions get a hearing—solutions rarely come from the top alone. Learning from mistakes and sharing successes shapes the day-to-day.
As interest grows in sustainable chemistry, we invest in greener pathways and solvent recycling. Our environmental engineers push us to capture every kilogram of waste and repurpose energy flows wherever possible. We see these investments not just as compliance, but as part of our legacy in responsible chemistry. Customers count on us to keep up with public concerns about chemical safety and environmental integrity, which ties our work as much to trust as to technical ability.
Seeing our material play a supporting role, whether in life-changing healthcare developments or high-tech materials, reminds us that quality chemicals fuel progress across industries. The people behind the manufacture—the operators, technical leads, and support staff—take pride in producing more than just a reagent; they offer reliability, partnership, and a promise of continued support, batch by batch.
