52079-67-1

Upstream product

• 1125-78-6 5,6,7,8-Tetrahydro-2-naphthol 
• 119-64-2 tetralin 
• 825-51-4 decahydronaphthalen-2-ol 
• 493-01-6 cis-decalin 
• 1196-55-0 4,4a,5,6,7,8-hexahydronaphthalen-2(3H)-one 
• 64-17-5 ethanol 
• 18852-51-2 sodium cyanoacetic acid ethyl ester 
• 1201-63-4 (+/-)-2ξ-hydroxy-(4arH,8acH)-decahydro-[2]naphthonitrile 
• 119-61-9 benzophenone 
• 36667-73-9 (+/-)-trans,cis-decahydro-2-naphthol 
• 71-43-2 benzene 
• 75-89-8 2,2,2-trifluoroethanol 
• 81827-61-4 trans-3,4,4a,5,6,7,8,8a-Octahydro-2-naphthalinyl-trifluormethansulfonat 
• 81827-64-7 trans-1,4,4a,5,6,7,8,8a-Octahydro-2-naphthalinyl-trifluormethansulfonat 

Downstream Products

• 493-02-7 trans-Decalin 
• 5746-69-0 (+/-)-trans,trans-decahydro-2-naphthol 
• 6635-50-3 octahydro-naphthalene-2,3-dione 
• 912291-06-6 (decahydronaphthalen-2-yl)-(3-trifluoromethylbenzyl)-amine hydrochloride 
• 58396-40-0 2-methylene-decahydro-naphthalene 
• 1579-21-1 cis-2-decalone 
• 4832-17-1 trans-decalin-2-one 
• 19295-16-0 (+/-)-6-phenyl-(4ar,8at)-1,2,3,4,4a,5,8,8a-octahydro-naphthalene 
• 7787-72-6 trans-2-Methylen-decahydronaphthalin 
• 493-01-6 cis-decalin 
• 825-51-4 (2R*,4aS*,8aR*)-decahydro-2-naphthol 
• 825-51-4 (2R*,4aS*,8aR*)-decahydro-2-naphthol 
• 15876-37-6 2-Oxo-trans-decalin-oxim 
• 76335-73-4 2,4-diphenyl-6,7-cyclohexano-3-azabicyclo<3.3.1>nonan-9-one 

Relevant academic research and scientific papers

A new regeneration system for oxidized nicotinamide cofactors

A novel regeneration system for oxidized nicotinamide cofactors (NAD + and NADP+) is presented. By combining 2,2′-azino-bis(3-ethylbenzthiazoline-6-sulphonic acid (ABTS)-catalyzed oxidation of NAD(P)H with laccase-catalyzed utilization of molecular oxygen as terminal oxidant, a simple chemo-enzymatic NAD(P)+ regeneration method is achieved. Thus, the advantages of both worlds, chemical oxidation of reduced nicotinamide cofactors and laccase-catalyzed utilization of oxygen from air are combined in a simple and generally applicable new approach for biooxidation catalysis. This new application of the well-known laccase-mediator system (LMS) is successfully used to promote alcohol dehydrogenase-catalyzed oxidation reactions of primary and secondary alcohols. Already under non-optimized conditions, high turnover numbers of > 300 and > 16000 were obtained for the nicotinamide cofactor and ABTS, respectively. In this communication, we present the proofof-principle and initial characterization of the proposed new regeneration system.

High trans-2-Decalones by Photoredox Catalyzed β-Isomerization

The synergistic combination of three catalytic processes – photoredox, enamine and hydrogen atom transfer (HAT) catalysis – enabled the β-isomerization of 2-decalones towards the thermodynamically most stable trans-isomers. A library of iridium (III) complexes and organic dyes were screened in combination with cyclic amines and thiols which after optimization gave the desired trans-2-decalones with high trans/cis ratios of 60 : 40 up to 98 : 2.

Enhancing Chemo- And Stereoselectivity in C-H Bond Oxygenation with H2O2by Nonheme High-Spin Iron Catalysts- And Role of Lewis Acid and Multimetal Centers

Spin states of iron often direct the selectivity in oxidation catalysis by iron complexes using hydrogen peroxide (H2O2) on an oxidant. While low-spin iron(III) hydroperoxides display stereoselective C-H bond hydroxylation, the reactions are nonstereoselective with high-spin iron(II) catalysts. The catalytic studies with a series of high-spin iron(II) complexes of N4 ligands with H2O2 and Sc3+ reported here reveal that the Lewis acid promotes catalytic C-H bond hydroxylation with high chemo- and stereoselectivity. This reactivity pattern is observed with iron(II) complexes containing two cis-labile sites. The enhanced selectivity for C-H bond hydroxylation catalyzed by the high-spin iron(II) complexes in the presence of Sc3+ parallels that of the low-spin iron catalysts. Furthermore, the introduction of multimetal centers enhances the activity and selectivity of the iron catalyst. The study provides insights into the development of peroxide-dependent bioinspired catalysts for the selective oxygenation of C-H bonds without the restriction of using iron complexes of strong-field ligands.

Ozonation of decalin as a model saturated cyclic molecule: A spectroscopic study

Ozonolysis is used for oxidation of a model cyclic molecule-decalin, which may be consid-ered as an analog of saturated cyclic molecules present in heavy oil. The conversion of decalin exceeds 50% with the highest yield of formation of acids about 15–17%. Carboxylic acids, ketones/aldehydes, and alcohols are produced as intermediate products. The methods of UV-visible, transmission IR, at-tenuated total reflection IR-spectroscopy, NMR and mass-spectrometry were used to identify reaction products and unravel a possible reaction mechanism. The key stage of the process is undoubtedly the activation of the first C-H bond and the formation of peroxide radicals.

ISOMERISATION REACTION

The present invention relates to the field of organic synthesis and more specifically to the isomerization of the β position of a β?trisubstituted C3-C70 carbonyl compound.

The debut of chiral cyclic (alkyl)(amino)carbenes (CAACs) in enantioselective catalysis

The popularity of NHCs in transition metal catalysis has prompted the development of chiral versions as electron-rich neutral stereodirecting ancillary ligands for enantioselective transformations. Herein we demonstrate that cyclic (alkyl)(amino)carbene (CAAC) ligands can also engage in asymmetric transformations, thereby expanding the toolbox of available chiral carbenes.

Iron Complex Catalyzed Selective C-H Bond Oxidation with Broad Substrate Scope

The use of a peroxidase-mimicking Fe complex has been reported on the basis of the biuret-modified TAML macrocyclic ligand framework (Fe-bTAML) as a catalyst to perform selective oxidation of unactivated 3° C-H bonds and activated 2° C-H bonds with low catalyst loading (1 mol %) and high product yield (excellent mass balance) under near-neutral conditions and broad substrate scope (18 substrates which includes arenes, heteroaromatics, and polar functional groups). Aliphatic C-H oxidation of 3° and 2° sites of complex substrates was achieved with predictable selectivity using steric, electronic, and stereoelectronic rules that govern site selectivity, which included oxidation of (+)-artemisinin to (+)-10β-hydroxyartemisinin. Mechanistic studies indicate FeV(O) to be the active oxidant during these reactions.

Alkane oxidation catalysed by a self-folded multi-iron complex

A preorganised ligand scaffold is capable of coordinating multiple Fe(II) centres to form an electrophilic CH oxidation catalyst. This catalyst oxidises unactivated hydrocarbons including simple, linear alkanes under mild conditions in good yields with selectivity for the oxidation of secondary CH bonds. Control complexes containing a single metal centre are incapable of oxidising unstrained linear hydrocarbons, indicating that participation of multiple centres aids the CH oxidation of challenging substrates.

From DNA to catalysis: A thymine-acetate ligated non-heme iron(III) catalyst for oxidative activation of aliphatic C-H bonds

A non-heme, iron(iii)/THA(thymine-1-acetate) catalyst together with H2O2 as an oxidant is efficient in oxidative C-H activation of alkanes. Although having a higher preference for tertiary C-H bonds, the catalyst also oxidizes aliphatic secondary C-H bonds into carbonyl compounds with good to excellent conversions. Based on the site selectivity of the catalyst and our mechanistic studies the reaction proceeds via an Fe-oxo species without long lived carbon centered radicals.

Selective activation of secondary C-H bonds by an iron catalyst: Insights into possibilities created by the use of a carboxyl-containing bipyridine ligand

In this work, we report the discovery of a carboxyl-containing iron catalyst 1 (FeII-DCBPY, DCBPY = 2,2′-bipyridine-4,4′- dicarboxylic acid), which could activate the C-H bonds of cycloalkanes with high secondary (2°) C-H bond selectivity. A turnover number (TN) of 11.8 and a 30% yield (based on the H2O2 oxidant) were achieved during the catalytic oxidation of cyclohexane by 1 under irradiation with visible light. For the transformation of cycloalkanes and bicyclic decalins with both 2° and tertiary (3°) C-H bonds, 1 always preferred to oxidise the 2° C-H bonds to the corresponding ketone and alcohol products; the 2°/3° ratio ranged between 78/22 and >99/1 across 7 examples. 18O isotope labelling experiments, ESR experiments, a PPh3 method and the catalase method were used to characterize the reaction process during the oxidation. The success of 1 showed that, in addition to using a bulky catalyst, high 2° C-H bond selectivity could also be achieved using a less bulky molecular iron complex as the catalyst.