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Lanthanum-lithium complex

Scheme 5.81 Shibasaki s direct aldol reaction mediated by the lanthanum-lithium complex 285 assumed structures of loaded intermediate catalysts 288 and 289. Scheme 5.81 Shibasaki s direct aldol reaction mediated by the lanthanum-lithium complex 285 assumed structures of loaded intermediate catalysts 288 and 289.
Catalytic Asymmetric Synthesis of Nitroaldols Using a Lanthanum-Lithium-BINOL Complex. [Pg.119]

CATALYTIC ASYMMETRIC SYNTHESIS OF NITROALDOLS USING A LANTHANUM-LITHIUM-BJNOL COMPLEX (2S,3S)-2-NITRO-5-PHENYL-1,3-PENTANEDIOL... [Pg.8]

ASYMMETRIC NITROALDOL REACTION USING LANTHANUM-LITHIUM-BINOL DERIVATIVE COMPLEX AS A CATALYST... [Pg.12]

This volume begins with two procedures in the area of catalytic asymmetric synthesis. The first procedure describes the synthesis of (R)-2-Dl PH ENYLPHOSPHI NO-2 -METHOXY-1,1 -BINAPHTHYL (MOP), a chiral ligand that has proven very useful in palladium-catalyzed hydrosilylation of olefins and palladium-catalyzed reduction of allylic esters by formic acid. The next procedure describes the catalytic asymmetric synthesis of nitroaldols using a chiral LANTHANUM-LITHIUM-BINOL COMPLEX, illustrated by the synthesis of (2S,3S)-2-NITRO-5-PHENYL-1,3-PENTANEDIOL. [Pg.284]

LLB lanthanum-lithium-binaphthoxide complex LaLi3tris(binaphthoxide)... [Pg.144]

Interestingly, almost the first results in asymmetric hydrophosphonylation with acyclic imines revealed that the lanthanum-potassium-BINOL catalyst LPB was more effective than the analog sodium and lithium complexes LSB and LLB, both of which have been shown to be highly efficient in asymmetric C-C bond formations (see Sect. 3). As a representative example, in the presence of LPB (20 mol%) and 5 equiv of dimethyl phosphite the hydrophosphonylation of im-... [Pg.167]

Electrical conductivity measurements have been reported on a wide range of polymers including carbon nanofibre reinforced HOPE [52], carbon black filled LDPE-ethylene methyl acrylate composites [28], carbon black filled HDPE [53], carbon black reinforced PP [27], talc filled PP [54], copper particle modified epoxy resins [55], epoxy and epoxy-haematite nanorod composites [56], polyvinyl pyrrolidone (PVP) and polyvinyl alcohol (PVA) blends [57], polyacrylonitrile based carbon fibre/PC composites [58], PC/MnCli composite films [59], titanocene polyester derivatives of terephthalic acid [60], lithium trifluoromethane sulfonamide doped PS-block-polyethylene oxide (PEO) copolymers [61], boron containing PVA derived ceramic organic semiconductors [62], sodium lanthanum tetrafluoride complexed with PEO [63], PC, acrylonitrile butadiene [64], blends of polyethylene dioxythiophene/ polystyrene sulfonate, PVC and PEO [65], EVA copolymer/carbon fibre conductive composites [66], carbon nanofibre modified thermotropic liquid crystalline polymers [67], PPY [68], PPY/PP/montmorillonite composites [69], carbon fibre reinforced PDMS-PPY composites [29], PANI [70], epoxy resin/PANI dodecylbenzene sulfonic acid blends [71], PANI/PA 6,6 composites [72], carbon fibre EVA composites [66], HDPE carbon fibre nanocomposites [52] and PPS [73]. [Pg.110]

Electrical properties have been reported on numerous carbon fiber-reinforced polymers, including carbon nanoflber-modified thermotropic liquid crystalline polymers [53], low-density polyethylene [54], ethylene vinyl acetate [55], wire coating varnishes [56], polydimethyl siloxane polypyrrole composites [50], polyacrylonitrile [59], polycarbonate [58], polyacrylonitrile-polycarbonate composites [58], modified chrome polymers [59], lithium trifluoromethane sulfonamide-doped polystyrene-block copolymer [60], boron-containing polyvinyl alcohols [71], lanthanum tetrafluoride complexed ethylene oxide [151, 72, 73], polycarbonate-acrylonitrile diene [44], polyethylene deoxythiophe-nel, blends of polystyrene sulfonate, polyvinyl chloride and polyethylene oxide [43], poly-pyrrole [61], polypyrrole-polypropylene-montmorillonite composites [62], polydimethyl siloxane-polypyrrole composites [63], polyaniline [46], epoxy resin-polyaniline dodecyl benzene sulfonic acid blends [64], and polyaniline-polyamide 6 composites [49]. [Pg.138]

Sasai H, Arai T, ShibasaM M. Catal3ftic as3fmmetric Michael reactions promoted by a lithium-free lanthanum-BINOL complex. J. Am. Chem. Soc. 1994 116(4) 1571-1572. [Pg.269]

Shibasaki made several improvements in the asymmetric Michael addition reaction using the previously developed BINOL-based (R)-ALB, (R)-6, and (R)-LPB, (R)-7 [1]. The former is prepared from (R)-BINOL, diisobutylaluminum hydride, and butyllithium, while the latter is from (R)-BINOL, La(Oz -Pr)3, and potassium f-butoxide. Only 0.1 mol % of (R)-6 and 0.09 mol % of potassium f-butoxide were needed to catalyze the addition of dimethyl malonate to 2-cy-clohexenone on a kilogram scale in >99% ee, when 4-A molecular sieves were added [15,16]. (R)-6 in the presence of sodium f-butoxide catalyzes the asymmetric 1,4-addition of the Horner-Wadsworth-Emmons reagent [17]. (R)-7 catalyzes the addition of nitromethane to chalcone [18]. Feringa prepared another aluminum complex from BINOL and lithium aluminum hydride and used this in the addition of nitroacetate to methyl vinyl ketone [19]. Later, Shibasaki developed a linked lanthanum reagent (R,R)-8 for the same asymmetric addition, in which two BINOLs were connected at the 3-positions with a 2-oxapropylene... [Pg.154]

This idea was realized very successfully by Shibasaki and Sasai in their heterobimetallic chiral catalysts [17], Two representative well-defined catalysts. LSB 9 (Lanthanum/Sodium/BINOL complex) and ALB 10 (Aluminum/Lithium/BINOL complex), are shown in Figure 8D.2, whose structures were confirmed by X-ray crystallography. In these catalysts, the alkali metal (Na, Li, or K)-naphthoxide works as a Br0nsted base and lanthanum or aluminum works as a Lewis acid. [Pg.573]

LDI-TOF mass spectral analysis of 49 revealed that the structure was a heterobimetallic complex consisting of one lanthanum, three lithiums, and three BINOL moieties.24 The relevant spectra are shown in Figure 10. LDI-TOF mass... [Pg.211]

Lithium lanthanum jr-allyl complexes, LiLn(All)4 dioxane, where Ln = Ce, Nd, Sm, Gd, Dy have been synthesized and used as catalysts in the polymerization of butadiene. The data show the predominance of 1,4-trans product. The catalytic activity of the lanthanides was nearly the same as evidenced by the percent yield in the range 78-90. [Pg.960]

For catalytic asymmetric aldol-type reactions, the transformation of the methylene compounds to a silyl enolate or a silyl ketene acetal was at one time necessary. Recently, the aldol reaction of aldehydes with non-modified ketones was realized by use of the lanthanum-Li3-trisf(/ )-bi-naphthoxidej catalyst 22 [18]. According to the proposed catalytic cycle, after abstraction of an a-proton from the ketone, the reaction between the lithium-enolate complex and the aldehyde... [Pg.108]

Graduate School of Pharmaceutical Sciences, The University of Tokyo, Japan Lanthanum(III)-Lithium-BINOL Complex [(/f)-LLB and (5)-LLB]... [Pg.542]

See other pages where Lanthanum-lithium complex is mentioned: [Pg.340]    [Pg.340]    [Pg.215]    [Pg.151]    [Pg.63]    [Pg.136]    [Pg.10]    [Pg.153]    [Pg.157]    [Pg.15]    [Pg.18]    [Pg.184]    [Pg.332]    [Pg.106]    [Pg.118]    [Pg.100]    [Pg.120]    [Pg.581]    [Pg.332]    [Pg.206]    [Pg.456]    [Pg.138]    [Pg.329]    [Pg.373]    [Pg.373]    [Pg.553]   
See also in sourсe #XX -- [ Pg.340 , Pg.341 ]



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Lithium complexes

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