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HS Code |
443123 |
| Product Name | (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) |
| Cas Number | 941678-49-7 |
| Molecular Formula | C17H24N4O2 |
| Molecular Weight | 316.40 |
| Appearance | White to off-white solid |
| Purity | Typically >98% |
| Smiles | CC(C)C1COC([C@@H]1N)C2=CC(=NC=C2)C3=NC(C(C)C)COC3 |
| Optical Purity | Enantiomerically pure (R,R) |
| Solubility | Soluble in common organic solvents (e.g., dichloromethane, acetonitrile) |
| Storage Conditions | Store at 2-8°C (refrigerated), protected from light and moisture |
As an accredited (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle containing 5 grams of (R,R)-2,2'-(2,6-pyridinediyl)bis(4-isopropyl-2-oxazoline), labeled with chemical name and hazard symbols. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) of (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline): Securely packed, moisture-protected, labeled drums or cartons ensuring safe chemical transit. |
| Shipping | This product, **(R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline)**, is shipped in tightly sealed containers under ambient temperature. It is packaged to prevent moisture and light exposure. Shipping complies with all relevant chemical safety and transport regulations. Proper documentation and MSDS are provided upon dispatch to ensure regulatory compliance and safe handling. |
| Storage | Store **(R,R)-2,2'-(2,6-pyridinediyl)bis(4-isopropyl-2-oxazoline)** in a tightly sealed container, protected from light and moisture, in a cool, dry, and well-ventilated area. Keep away from incompatible substances such as strong acids and oxidizers. Ensure proper labeling and use only in a chemical fume hood. Follow all standard laboratory safety protocols during handling and storage. |
| Shelf Life | Shelf life: Store `(R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline)` in a cool, dry place; stable for at least 2 years. |
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Purity 99%: (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) with 99% purity is used in asymmetric catalysis, where it ensures high enantioselectivity in metal-ligand complex formation. Melting Point 172°C: (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) with a melting point of 172°C is used in high-temperature ligand screening, where it provides thermal stability during catalyst synthesis. Molecular Weight 334.46 g/mol: (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) at 334.46 g/mol is used in homogeneous catalysis research, where it enables reproducible stoichiometry in ligand-to-metal ratio calculations. Solubility in Acetonitrile: (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) with high solubility in acetonitrile is used in coordination chemistry studies, where it promotes uniform ligand dispersion in solution-phase reactions. Optical Activity [α]20/D +78 (c=1, CHCl3): (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) exhibiting [α]20/D +78 is used in chiral ligand screening, where it ensures consistent stereoselective induction in catalytic transformations. Stability Temperature up to 200°C: (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) stable up to 200°C is used in high-temperature catalytic reactions, where it maintains integrity under rigorous reaction conditions. Particle Size <50 µm: (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) with particle size below 50 µm is used in automated synthesis platforms, where it enables rapid dissolution and homogeneous reaction mixtures. |
Competitive (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) prices that fit your budget—flexible terms and customized quotes for every order.
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Anyone who has spent years in chemical manufacturing knows that consistency makes or breaks a project. Walk into our production hall on a busy morning and you’ll find vessels loaded, reactors humming, and technicians checking readings. We aren’t just mixing ingredients — we’re crafting precise compounds that drive research forward. (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) comes off our lines after a careful sequence of steps, overseen by people who know the science and the stakes.
The raw materials for this molecule demand rigorous control. Any deviation, and the whole batch loses value. Over the years, we have learned which suppliers deliver the cleanest feedstock, and which corners of the process allow for the tightest windows.
Every bottle leaving our site reflects months of fine-tuning. Spec sheets list things like melting point, HPLC purity, and residual solvent content. In practice, what matters is how these numbers play out during real-world synthesis. Customers in academia and at leading catalyst research labs have called to tell us: “Your batch ran reliably — no surprises.” This feedback shapes our work as much as QC data does.
Each production run puts us in front of new challenges. Sometimes a shift in humidity slips in, especially during the summer, nudging purification curves or complicating crystallization. We keep backup pumps and drying ovens running, so every shipment lands within specification.
Chemists reach for this ligand when building chiral catalysts, especially those involving transition metals such as copper or nickel. Over the last decade, the trend has moved toward more sustainable, selective reactions. Our (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) sits at this crossroads — not because brochures say so, but thanks to observed performance in asymmetric catalysis.
Researchers at pharmaceutical companies often mention time pressure and the need to minimize rework. They look for batch-to-batch reproducibility, low baseline impurities, and material that doesn’t stall purification steps. We build these requirements into our process: high-purity solvent washes, double recrystallization, and dense documentation for every drum.
Customers pursuing fine chemical synthesis or natural product modification point out another need — robust batch stability. Product needs to stay consistent, whether it’s opened fresh or sampled from a drum that’s been sitting for months. We run long-term stability checks in-house, tracking results through each season to spot trends before they become problems.
Take purity, for instance. We use HPLC, NMR, and mass spectrometry to verify that every run matches the reference spectrum. In reality, it’s the technician watching the crystal crop during drying, and the chemist noting if filtration yields drift, who decide if a lot meets the mark. This process gives us confidence that when a customer sets up a metal complexation, product performance follows as expected.
Physical handling matters too. The compound’s consistency translates directly to weighing accuracy, ease of dissolution, and reaction predictability. Powders flow differently depending on humidity and particle size; we grind, sieve, and run small-scale dissolution checks, so nothing leaves untested.
Transport and storage throw up yet another set of variables. Bulk drums often cross half a continent, exposed to temperature swings. We’ve studied how different types of inner liners, capping solutions, and external packaging maintain protection, and made adjustments along the way. Powder that cakes is a sign something needs rethinking — we have responded to feedback by adjusting particle sizes and exploring new packaging solutions to keep the product usable for every application.
Direct conversations help us learn how material works in field conditions. A team at a specialty chemical company once flagged some off-spec color arising after extended storage; they traced it to a trace impurity. We ran a full process trace, identified a hot spot in the final crystallization solvent, and switched supplier lots. From then on, we added extra checks in that section — it’s now standard practice.
Academic users send us spectra and discuss odd results. Once, a group found abnormally slow ligand exchange rates during catalyst formation. Careful dig-through of their process and ours tracked it down to a subtle change in water content during our drying cycle. Tweaking our vacuum parameters brought the product back into alignment with literature values.
Our manufacturing database now logs every customer report next to run conditions, so minor hitches drive real process changes. It’s not only metrics that steer improvement, but direct outcomes from the labs using the product.
There are many chiral ligands in the market, each with enthusiasts and specific drawbacks. Some offer low cost or easy handling, others hit outstanding selectivity in narrow applications. The (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) distinguishes itself in two key ways.
First, it combines strong chelation power with real selectivity for chiral induction. Customers share that this translates to cleaner reactions and less time spent chasing side products. Second, our experience shows this ligand holds up across a broader set of metal complexes. Instead of sticking strictly to copper or nickel, project teams find it delivers in magnesium and other less-common systems. Our manufacturing tweaks — from solvent selection to reaction atmosphere — follow these insights.
We have looked hard at competitor samples reported in the literature and occasionally sent by comparison-hunting customers. Generic material sometimes lands with solvent inclusions, uneven particle size, or mixed stereochemistry. To address this, we set up batch-specific enantiomeric excess testing and install tighter purity cutoffs than current industry baseline standards demand.
Over-optimizing one metric, like particle size, sometimes comes at the expense of other features, such as easy dispersion in polar or non-polar media. Our team has found through side-by-side trials that a balanced approach works better — we trade slight uniformity for reliable solubility across multiple solvent systems, after listening to customer feedback.
Our clients range from small research outfits scaling up new routes to pharmaceutical manufacturers rolling projects into pilot phase. Each application puts new demands on product behavior.
In one instance, a customer needed gram-scale samples to test a library of asymmetric syntheses. They needed to weigh out precise amounts, dissolve everything on the first try, and avoid clouding or precipitate in stirred reactors. By tuning our milling process, we smoothed out inconsistencies and made sure every lot delivered steady performance.
Production chemists demand thousands of grams with the same quality as pilot lots. We invested in scalable purification, so 10-gram vials behave like 10-kilogram drums. Any drift shows up, and we course-correct long before delivery.
Whenever a client pushes for custom-cut batch sizes or new forms — say, a finer grind for multi-parallel reactors — we pull samples from several lines and test them in-house. Techniques refined in our plant avoid the guesswork that frustrates downstream users.
Traceability plays an outsized role in delivering trusted specialty chemicals. It starts with raw material logbooks and ends in a batch history that follows every shipment. If someone calls six months down the line, asking about a drum’s origin or the exact atmospheric content during sealing, we pull the record without missing a beat.
We tag each batch with unique identifiers, so side-by-side comparisons between runs can highlight any unnoticed drift. This helps both us and our users pinpoint sources of any outlier performance, saving weeks of troubleshooting.
Timing matters too. Researchers juggling deadlines need to know their order will actually arrive. Our inventory team carries buffer stock, but more than once, spikes in academic grant projects have stretched our schedule thin. Robust planning — advance warnings from returning customers, transparent lead times, and honest projections — have helped close all but the crunchiest gaps.
Global supply lines have seen unpredictable swings over the last few years, from raw material shortages to delays at export checkpoints. Tight-knit relationships with our suppliers absorb some of the shock, but not all. In those rare cases where something goes sideways, we keep customers in the loop, share what’s happening, and propose realistic alternatives, be it reserving reserved stock, dropping in a backup product, or fast-tracking smaller runs.
Our lab team reviews every run for possible contamination sources. When new analytical techniques arrive, we re-examine old assumptions, update our test panels, and search for previously missed impurities. This ongoing vigilance keeps our product line sharp, even as external trends evolve.
Over the years, our operations crew has seen cycles in demand, regulatory changes, and shifting customer expectations. Every shift puts theory to practical test. Our chemists know that overlooked mechanical details can snowball into major headaches. Loss of consistency in filtration, slight temperature drifting during scale-up, or a pipetting misstep can nudge a product batch off target.
Training and open communication close the gaps. Weekly floor meetings go over process changes, discuss near-misses, and swap notes about how specific measures delivered — or failed to deliver — under production stress. Bottling wisdom into everyday routines cuts future risk and keeps us honest about what works on a real-world production line.
All chemical manufacturing brings responsibility. Handling (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) involves careful PPE use, routine spill drills, and regular training updates. We have safety showers, exhaust hoods, and emergency plans ready, not as paperwork formality, but because a slipped drum or a cracked valve becomes everyone’s concern.
Disposal and emissions sit close to our process design. Waste solvents and spent filters run through a multi-step treatment before leaving our site. Every batch’s environmental footprint is tracked, and periodic audits run independently of regulatory minimums. This habit saves hassle — lines run cleaner, and staff know the expectations inside-out. Some customers have asked for downstream waste handling data, which we share in full.
For many clients, knowing that a manufacturer stands behind their procedures brings peace of mind. Our approach means problems get logged, reviewed, and fixed, not buried. New team members shadow experienced operators for months, and our open-door policy brings process concerns straight to the top.
Stories stand out more than numbers. One partner, late one evening, described the crunch of an upcoming regulatory re-qualification. He needed material certified free of a new regulated solvent — not a minor change. We retooled a section of the process, ran new analytics, and delivered the documentation within the deadline. Small changes, made quickly, kept an entire program on track.
If a researcher finds their results out-of-step with published work, we roll up sleeves and go line-by-line through their setup. Sometimes the material checks out. Sometimes it’s as simple as an air leak in their glovebox. Either way, we’re glad to walk the path together — open ears and straight talk beat email chains and call centers.
The market keeps shifting, and new ligands appear in journals, each promising unique performance. Our role isn’t to anchor to old ways, but to keep our product at the point where it delivers reliably for real users. That only happens by working closely with customers, listening to the problems they face, and investing in transparent, resilient production.
Each improvement grows out of lessons learned on the production floor — not just new analytical tools, but late-night conversations, near-misses, and experiments that work after all others fail. We have the scars, the experience, and the commitment to turn (R,R)-2,2'-(2,6-Pyridinediyl)Bis(4-Isopropyl-2-Oxazoline) from a name on a label into a material that researchers trust, time after time.
