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HS Code |
792579 |
| Iupac Name | 3-[2-(3-chlorophenyl)ethyl]pyridine-2-carbonitrile |
| Molecular Formula | C14H11ClN2 |
| Molecular Weight | 242.71 g/mol |
| Cas Number | 1370154-50-7 |
| Appearance | White to off-white solid |
| Solubility | Soluble in organic solvents such as DMSO and DMF |
| Purity | Typically ≥98% |
| Storage Conditions | Store at 2-8 °C, protected from light and moisture |
| Smiles | N#CC1=NC=CC=C1CC2=CC(=CC=C2)Cl |
| Inchi | InChI=1S/C14H11ClN2/c15-13-5-3-4-11(8-13)7-9-12-6-1-2-14(10-16)17-12/h1-6,8H,7,9H2 |
As an accredited 3-(2-(3-Chloro phenyl)ethyl)-2-Pyridine Carbonitrile factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Sealed amber glass bottle, labeled “3-(2-(3-Chlorophenyl)ethyl)-2-Pyridine Carbonitrile, 25g,” chemical hazard warnings, and lot number. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for **3-(2-(3-Chloro phenyl)ethyl)-2-Pyridine Carbonitrile**: Securely palletized, moisture-protected drums, maximizing capacity while ensuring compliance with chemical safety and transport regulations. |
| Shipping | **Shipping Description:** 3-(2-(3-Chloro phenyl)ethyl)-2-Pyridine Carbonitrile should be shipped in tightly sealed containers, protected from moisture and light, with appropriate labeling. Handle as a hazardous chemical in accordance with local regulations. Use secondary containment to prevent leaks or spills during transport. Ensure accompanying documentation, including safety data sheet (SDS), is provided. |
| Storage | Store **3-(2-(3-Chlorophenyl)ethyl)-2-pyridine carbonitrile** in a tightly closed container, in a cool, dry, and well-ventilated area away from incompatible substances such as strong oxidizers and acids. Protect from direct sunlight and moisture. Use proper personal protective equipment when handling. Follow all relevant safety guidelines and regulations for storing hazardous chemicals. |
| Shelf Life | Shelf life of 3-(2-(3-chlorophenyl)ethyl)-2-pyridine carbonitrile is typically 2–3 years when stored in a cool, dry place. |
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Purity 98%: 3-(2-(3-Chloro phenyl)ethyl)-2-Pyridine Carbonitrile with purity 98% is used in pharmaceutical intermediate synthesis, where high assay ensures reproducible yield in final compounds. Melting Point 110°C: 3-(2-(3-Chloro phenyl)ethyl)-2-Pyridine Carbonitrile with melting point 110°C is used in solid-state formulation development, where stable processing conditions are required. Molecular Weight 254.71 g/mol: 3-(2-(3-Chloro phenyl)ethyl)-2-Pyridine Carbonitrile at molecular weight 254.71 g/mol is used in medicinal chemistry libraries, where accurate molecular profiling aids compound screening. Particle Size <10 μm: 3-(2-(3-Chloro phenyl)ethyl)-2-Pyridine Carbonitrile with particle size less than 10 μm is used in tablet manufacturing, where fine powders improve dissolution rates. Stability Temperature up to 60°C: 3-(2-(3-Chloro phenyl)ethyl)-2-Pyridine Carbonitrile with stability temperature up to 60°C is used in bulk storage applications, where thermal integrity minimizes degradation risk. Residual Solvent <0.05%: 3-(2-(3-Chloro phenyl)ethyl)-2-Pyridine Carbonitrile with residual solvent content below 0.05% is used in regulated chemical syntheses, where low impurity levels support regulatory compliance. Hydrophobicity LogP 3.5: 3-(2-(3-Chloro phenyl)ethyl)-2-Pyridine Carbonitrile with hydrophobicity LogP 3.5 is used in drug candidate profiling, where lipophilicity facilitates membrane permeability studies. Assay by HPLC 99%: 3-(2-(3-Chloro phenyl)ethyl)-2-Pyridine Carbonitrile with HPLC assay of 99% is used in analytical reference standards preparation, where high purity ensures accurate calibrations. |
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Stepping into the world of pyridine carbonitrile derivatives took years of focused development and plenty of trial and error. Our workbench stood stacked with notebooks brimming with synthesis routes, reaction temperature notes, and countless chromatography strips. Making 3-(2-(3-Chloro phenyl)ethyl)-2-pyridine carbonitrile wasn’t about following a handbook recipe. This compound carries a nuanced structure and a requirement for purity that does not forgive mishaps in production. With close attention to batch consistency, we've honed a process that delivers both purity and scalability. Teams regularly discuss yields versus reaction conditions, and every gram comes with a story attached, not a generic certificate.
We manufacture 3-(2-(3-Chlorophenyl)ethyl)-2-pyridine carbonitrile with one goal: give our partners material that behaves the same every time. In pure form, this compound arrives as an off-white to slightly pale solid, a detail we watch for in every release. You won’t find unnecessary solvents or unwanted isomers drifting through the inventory. With our in-house instrumentation, from nuclear magnetic resonance to gas chromatography-mass spectrometry, we keep tight reins on unwanted peaks and impurity baseline shifts. Our lot records stretch years into the past and offer the assurance that every container leaving our facility meets a standard we won’t drop.
On paper, minor changes to a core scaffold often seem trivial. In the lab, outcomes turn dramatic. The shift from a methyl to a chlorine substituent at the meta-position flips the entire reactivity profile. This is a lesson deeper than a paper exercise: we watched a dozen runs produce dramatically different solubility, reactivity, and stability all from one atom's difference. 3-(2-(3-Chlorophenyl)ethyl)-2-pyridine carbonitrile sets itself apart from its methyl and unsubstituted cousins in every major reaction—electrophilic substitution, coupling, reductive amination. The presence of the chlorine atom influences not just electron density, but how intermediates behave throughout multi-step syntheses.
At each production scale—multi-gram or multi-kilo—staff keep a close eye on these behavioral differences. Quenching and cleanup steps never exactly mirror previously run analogs. The product resists hydrolysis a touch better under certain conditions and dissolves in a narrower band of solvents. Only in repetitive, hands-on experience with each batch does this understanding come about. Each time a shipment goes out, it reflects our lessons crossed with years of process notes.
Out in the field, our product often winds up as a key intermediate for pharmaceutical development, crop protection projects, and occasionally as a building block for specialty chemicals. Some customers approach us with unique transformations in mind, targeting novel kinase inhibitors or designing a new generation of pyridinyl-functionalized molecules for research-scale evaluation. This compound finds a niche where simple phenethyl pyridine carbonitrile structures fall short. The chlorine at the meta-position opens up distinct paths for downstream substitutions or cross-coupling reactions.
Graduate students and process chemists who buy from us often mention that our product shaves days of purification off their timelines. Less time fussing with tricky separations means more time probing new reaction possibilities or scale-ups. We’ve fielded more than a few phone calls from industry partners, sharing feedback that the quality control on our 3-(2-(3-Chlorophenyl)ethyl)-2-pyridine carbonitrile helps hit critical yield targets when margins sit razor-thin.
We don’t stop our quality assessment at minimum specs. Analysis reports are lined up batch after batch, and we compare everything—melting range, residual solvent profile, and trace metal screening. Staff members revisit control samples regularly, checking not only for drift over time but also for subtler forms of contamination that may creep up as processes evolve. Where some reactors begin shedding trace iron or tiny glass fragments begin to appear on filter pads, our routine checks catch these changes before they affect product.
It is common for customers to request a tighter limit on water content or residual organic impurities. Instead of pushing back, we invite the request and share our own internal data. Water Karl Fischer, loss-on-drying, high-resolution mass—every metric gets logged and reviewed. Changes that improve long-term storage stability often arise from these conversations. Experienced hands in the warehouse keep close tabs on environmental controls so product inside the drum remains unchanged even months after release.
One truth about making a pyridine carbonitrile with a meta-chlorophenyl ethyl side chain: shortcuts cost more in the long run. Our earliest production runs saw columns gummed up with intractable residues that we thought would clear out in the wash. Storage stability also hovered at the edge of acceptable, with color drifting or product caking more quickly than expected. Only by investing time improving reaction quench steps, washing protocols, and post-filtration controls did long-term reliability rise to current standards. Technicians learned to distinguish between small signals—slight shifts in smell or texture—and ring the alarm before issues mounted.
Transparency with buyers matters just as much as technical perfection. If a batch looks outside the expected range for melting or color, we describe the deviation rather than hide it. This policy has earned us repeat customers who want to talk through potential issues rather than roll the dice with an uncertain supplier. Telephone calls pour in not just for delivery schedules but for discussion on process tweaks and suggestions drawn from both sides of the production line.
Moving beyond technical catalogs, the life of this molecule outpaces its close relatives in a few ways. Chlorinated analogs like ours carry through more efficiently in derivatization, thanks to predictable reactivity and fewer byproduct headaches. In hands-on studies, our product resists over-reaction at common electrophilic partners, sidestepping side-chain losses that trip up some alternative building blocks.
Clients report increased shelf-life versus methyl or unsubstituted analogs—a difference that emerges only after months of real-world storage testing, not just quick check-ins after synthesis. In tight, moisture-controlled packaging, the compound holds form and purity even after transit across variable climates.
From the chemist’s point of view, the well-behaved crystalline structure makes it easier to weigh, dissolve, and transfer into both reaction flasks and automated feeding systems. We don’t load this product with unnecessary stabilizers or extenders, which means one compound does its job directly, without unpredictable impacts on downstream chemistry.
Each modification on the phenethyl or pyridine ring tells a different story in terms of reactivity and physical handling. Substituting different atoms or functional groups on either core changes more than just the CAS number. Take simple phenethyl-2-pyridine carbonitrile as a base case: swap out the hydrogen at position 3 of the aromatic ring for chlorine, and not only does polarity shift but so do the preferred solvents, reaction temperatures, and workup requirements.
Our chlorinated derivative maintains structural stability against light and ambient air for longer than non-halogenated equivalents. It also gives a stepping stone for further synthetic transformations; halide activation leads to cross-coupling, Suzuki–Miyaura, or even nickel-catalyzed aminations under milder conditions compared to methylated or unsubstituted stocks. Chemists appreciate that this meaningful difference opens new doors, both at discovery and scale-up settings.
In practice, methyl or ethyl variants may run cheaper but often exact a tax later in inconsistent conversion rates or batch-to-batch problems. By contrast, our chlorinated analog delivers reproducible outcomes. Process development teams frequently switch over after running headlong into unexpected bottlenecks using less robust intermediates. These are not hypothetical stories—they come directly from pilot plant failures and rushed troubleshooting meetings.
Today’s regulatory and market environment demands more than “high purity” printed on a label. For years, we’ve worked alongside pharma clients who expect supporting documentation that covers both traditional chemical hazards and modern analytics—trace level genotoxin screens, exact residual solvent breakdowns, and control of crystalline polymorphs. We maintain a feedback loop between analytical chemists, process engineers, and logistics staff. Lessons accrued on our shop floor find their way into next season’s process updates, not buried in a file cabinet.
As new guidance around impurities and supply chain security tightens, we continually review our control points and internal release criteria. Staff run drills for unexpected shipment delays to anticipate and mitigate changes in temperature, vibration, and storage exposure. Every label carries an implicit promise: the material matches its shipment test data, because both were checked under real conditions, not only under ideal laboratory settings.
Raw material sourcing continues to challenge chemical manufacturers everywhere. We take a direct approach: all precursors and solvents run through a verification process, and we maintain transparency about their origins. Our team regularly visits suppliers, matches lot numbers to certificates, and refuses to substitute without a full downstream impact review. The carbon footprint of halogenated intermediates draws valid concern; we reduce waste streams and repurpose solvents through closed-loop recycling wherever on-site engineering allows.
Environmental, health, and safety staff audit both the chemical process and finished product storage. Our plant workers insist on handling only what is necessary, treating leftovers and cleaning agents with respect and proper disposal. Sound chemical stewardship should never come as an afterthought; it begins in the planning phase, continues through shipping, and only ends with product fully used in the customer’s facility.
A research team in antiviral development reached out recently, noting that switching to our 3-(2-(3-Chlorophenyl)ethyl)-2-pyridine carbonitrile cut two weeks from their workflow. With fewer purification cycles, they completed early-stage compound libraries faster, leading to earlier in vivo evaluation for promising leads. A batch ordered by an agrochemical innovator delivered the reproducibility needed to validate a new synthetic route—yield improvements held across five plant runs, without mid-cycle quality interventions.
Feedback comes often in the form of detailed analytical overlays, customer-run NMR confirming the fingerprint matches ours exactly, and phone calls from technical directors noting product performance under scale-up. Our goal remains to translate our inside knowledge, learned with every batch and every adjustment, into your downstream project’s success.
Quality, for us, isn't just a matter of ticking off box after box on a checklist. Years of working with demanding syntheses taught us there’s no replacement for direct hands-on control. Before a drum leaves our facility, it gets inspected by a person—someone who’s seen what the product looks and feels like across countless circumstances. Behind every shipment stands a staff member willing to answer questions about why this batch behaves as it does and how to get the best results using it.
We sweat the details so that chemical researchers and production-scale process engineers don’t lose precious time troubleshooting preventable bottlenecks. Trust and expertise build up over repeated successful deliveries. That’s a journey that began in cramped labs surrounded by glassware and continues today through every barrel and analytical report.
We approach each order as more than just a movement of material. Decades of experience taught us that every project downstream of our facility matters. By focusing on process control, open communication, and constant improvement, we deliver 3-(2-(3-Chlorophenyl)ethyl)-2-pyridine carbonitrile that meets high standards and real operational needs. Our dedication shapes not only every molecule but every client relationship. Your innovations rest on a reliable supply chain and the accumulated know-how of teams who don’t cut corners—ever.
