Copper!II triflate

Cupric trifluoromethylsulfonate (copper II triflate) [34946-82-2] M 361.7, pK <-3.0 (for triflic acid). Dissolve in MeCN, add dry Et20 until cloudy and cool at -20° in a freezer. The light blue ppte is collected and dried in a vacuum oven at 130°/20mm for 8h. It has Xmax 737nm (e 22.4M cm ) in AcOH. [J Am Chem Soc 95 330 1973], It has also been dried in a vessel at O.lTorr by heating with a Fischer burner [J Org Chem 43 3422 1978], It has been dried at 110-120°/5mm for Ih before use and forms a benzene complex which should be handled in a dry box because it is air sensitive [Chem Pharm Bull Jpn 28 262 I980-, J Am Chem Soc 95 330 1973]. 

In a similar reaction, lithium enoiates, RC(OLi)=CH2, were dimerized to 1,4-diketones, RCOCH2CH2COR, with CUCI2, FeCl3, or copper(II) triflate, in a nonprotic solvent." ... 

Ghosh et al. [70] reviewed a few years ago the utihty of C2-symmetric chiral bis(oxazoline)-metal complexes for catalytic asymmetric synthesis, and they reserved an important place for Diels-Alder and related transformations. Bis(oxazoline) copper(II)triflate derivatives have been indeed described by Evans et al. as effective catalysts for the asymmetric Diels-Alder reaction [71]. The bis(oxazoline) Ugand 54 allowed the Diels-Alder transformation of two-point binding N-acylimide dienophiles with good yields, good diastereos-electivities (in favor of the endo diastereoisomer) and excellent ee values (up to 99%) [72]. These substrates represent the standard test for new catalysts development. To widen the use of Lewis acidic chiral Cu(ll) complexes, Evans et al. prepared and tested bis(oxazoHnyl)pyridine (PyBOx, structure 55, Scheme 26) as ligand [73]. 

The reaction of 1,3-cyclohexadiene and ethylglyoxylate catalyzed by the corresponding copper (II) triflate complex led to the expected product in high yield (81%) and high enantio- and diastereoselectivity. At - 40 °C, the reaction between cyclohexadiene and diethyl mesoxalate afforded similarly the expected product in high yield and up to 98% ee. 

The carbene-copper complex was not isolated but generated in situ by deprotonation of the imidazolinium salt 77 by n-BuLi in ether, in the presence of copper(II) triflate (Scheme 51). The use of two equivalents of ligand caused a dramatic decrease in reactivity. 

Chiral //A(oxazolinc) ligands disubstituted at the carbon atom linking the two oxazolines by Frechet-type polyether dendrimers coordinated with copper(II) triflate were found to provide good yields and moderate enantioselectivities for Mukaiyama aldol reactions in water that are comparable with those resulting from the corresponding smaller catalysts.291 AgPF6-BINAP is very active in this reaction and the addition of a small amount of water enhanced the reactivity.292... 

Smooth and efficient cyclopropanation also occurs with copper(II) triflate and diazomethane. Intra- and intermolecular competition experiments show that, in this case, the less substituted double bond reacts preferentially251. The same is true for CuOTf and Cu(BF4)2, whereas with CuX P(OMe)3 (X = Cl, I), CuS04 and cop-per(II) acetylacetonate, cyclopropanation of the more substituted double bond predominates. An example is given for cyclopropanation of 1. 

Copper(II) triflate has also been used for the carbenoid cyclopropanation reaction of simple olefins like cyclohexene, 2-methylpropene, cis- or rran.y-2-butene and norbomene with vinyldiazomethane 2 26,27). Although the yields were low (20-38 %), this catalyst is far superior to other copper salts and chelates except for copper(II) hexafluoroacetylaeetonate [Cu(hfacac)2], which exhibits similar efficiency. However, highly nucleophilic vinyl ethers, such as dihydropyran and dihydrofuran cannot be cyclopropanated as they rapidly polymerize on contact with Cu(OTf)2. With these substrates, copper(II) trifluoroacetate or copper(II) hexafluoroacetylaeetonate have to be used. The vinylcyclopropanation is stereospecific with cis- and rra s-2-butene. The 7-vinylbicyclo[4.1.0]heptanes formed from cyclohexene are obtained with the same exo/endo ratio in both the Cu(OTf)2 and Cu(hfacac)2 catalyzed reaction. The... 

Copper(II) triflate is quite inefficient in promoting cyclopropanation of allyl alcohol, and the use of f-butyl diazoacetate [164/(165+166) = 97/3%] brought no improvement over ethyl diazoacetate (67/6 %)162). If, however, copper(I) triflate was the catalyst, cyclopropanation with ethyl diazoacetate increased to 30% at the expense of O/H insertion (55%). As has already been discussed in Sect. 2.2.1, competitive coordination-type and carbenoid mechanisms may be involved in cyclopropanation with copper catalysts, and the ability of Cu(I) to coordinate efficiently with olefins may enhance this reaction in the intramolecular competition with O/H insertion. 

The dominant role of the traditional copper catalysts, generally used under heterogeneous conditions, has not been challenged as yet. Only a few reports shed light on the efficiency of alternative catalysts. Copper(II) triflate allows high-yield intramolecular cyclopropanation of y,8-unsaturated diazoketone 182160) it is superior to CuS04 (53 % yield 192 ) or Rh2(OAc)4160). The solvent is crucial for an efficient conversion If the reaction is carried out in ether, the solvent competes with the double bond for the electrophilic metal carbene to give 184, presumably via an oxonium ylide intermediate. 

Glycosyl esters with remote functionality constitute a relatively new class of O-carbonyl glycosyl donors, which fulfill the prospect of mild and chemoselective activation protocols (Scheme 3.22). For example, Kobayashi and coworkers have developed a 2-pyridine carboxylate glycosyl donor 134 (Y = 2-pyridyl), which is activated by the coordination of metal Lewis acid (El+) to the Lewis basic pyridine nitrogen atom and ester carbonyl oxygen atom [324]. In the event, 2-pyridyl (carbonyl) donor 134 and the monosaccharide acceptor were treated with copper(II) triflate (2.2 equiv) in diethyl ether at —50 °C, providing the disaccharide 136 in 70% (a P,... 

In 1993, Evans and co-workers examined phe-box 6, /-pr-box 45, and bu-box 3 ligands in the Diels-Alder reaction of cyclopentadiene 68 and 3-acryloyl-l,3-oxazolidin-2-one 69 using a weak Lewis acid such as copper(II) triflate." The results are summarized in Table 9.9. The reaction was carried out between —50 and —78 °C for 3-18 h and achieved selectivities of up to 98 2 (endo/exo) with an endo ee of >98% (using bu-box 3). Interestingly, the enantiomer produced in these reactions was the (25) configuration, compared to the (2K) isomer obtained with iron(III) and magnesium(II) as reported by Corey. This observed stereochemistry was explained by the chelation model of the copper(II) complex 74 (Fig. 9.23)... 

Ghosh and co-workers have also demonstrated that the Cu(II)-bis(oxazoline) complexes of conformationally constrained inda-box ligands 9a and ent-9a are excellent catalysts for the enantioselective Diels-Alder reaction. Using copper(II) trrflate as the metal source, the reaction resulted in selectivities up to >99 1 endo/ exo ratio with endo ee up to 99% (2R isomer), as shown in Table 9.10 (Fig. 9.24). Of particular interest, Cu(II)-phe-box ligand 6-derived catalyst complex exhibited considerably lower enantioselectivity (30%)." Furthermore, they have shown that the use of Mg(II) as the chelating metal resulted in a reversal of stereochemistry [up to 98 2 endo/exo and 61% endo ee for the (25) isomer]. Davies also showed that the use of copper(II) triflate with his stmcturally related inda-box ligands 9b and 34a led to similar selectivities. 

J0rgensen and co-workers showed that in the presence of bu-box ligand 3 complexed with copper(II) triflate or phe-box ligand ent-6 complexed with copper(Il) triflate, the above reaction proceeded in a combined yield of up to 86% with product ratios (106 107) varying from 1 2 to 2 1 and ee between 77 and 95% for either product (Table 9.17, Fig. 9.35a). ... 

It has been shown that complete selectivity for the hetero-Diels-Alder cycloadduct 109 (100% endo, 60% ee) can be achieved in the hetero-Diels-Alder reaction of 1,3-cyclohexadiene 108 and ethyl glyoxylate 99 using ent-6 and copper(II) triflate derived catalyst complex. Another interesting reaction introduced by Jprgensen and co-workers was the reaction between 1,3-cyclohexadiene 108 and diethyl ketomalonate 110 to form cycloadduct 111 in 76% yield with an ee of 84% (Fig. 9.35b, p. 558). ... 

Ghosez and co-workers also presented a hetero-Diels-Alder reaction using a hetero-atom-containing diene 121 and the oxazolidinone 80a in the presence of bu-box 3 complexed with copper(II) triflate to afford the cycloadduct 122 in 80% yield (>99 1 exo/endo, 95% ee) as shown in Figure 9.38Z . ... 

Mukiayama aldol reactions between silyl enol ethers and various carbonyl containing compounds is yet another reaction whose stereochemical outcome can be influenced by the presence of bis(oxazoline)-metal complexes. Evans has carried out a great deal of the work in this area. In 1996, Evans and coworkers reported the copper(II)- and zinc(II)-py-box (la-c) catalyzed aldol condensation between benzyloxyacetaldehyde 146 and the trimethylsilyl enol ether [(l-ferf-butylthio)vinyl]oxy trimethylsilane I47. b82,85 Complete conversion to aldol adduct 148 was achieved with enantiomeric excesses up to 96% [using copper(II) triflate]. The use of zinc as the coordination metal led to consistently lower selectivities and longer reaction times, as shown in Table 9.25 (Eig. 9.46). 

In 1997, Evans reported on the aldol reaction using the same enol ether 147 with a variety of glyoxylates and pyruvates using tin triflate and copper triflate. As shown in Table 9.26 (Fig. 9.47a), reaction of several pyruvates using bu-box ligand 3 complexed with copper(II) triflate afforded yields of up to 99% with selectivities up to 96% (ee) for adduct 150. " ... 

Evans also investigated the aldol condensation between methyl pyruvate 151 and several different substituted enol ethers 152, again using bu-box 3 and copper(II) triflate. These reactions achieved selectivities up to 98 2 (syn/anti) with syn ee up to 98% and yields up to 96% (Table 9.27, Fig. 9.47h). " ... 

A few examples are available in which regiocontrol in the cyclopropanation of non-conjugated diene is catalyst-dependent. An early example is showed in equation 118. Copper(II) triflate catalysed cyclopropanation of diene 132 with diazomethane occurs preferentially at the less substituted double bond, whereas copper(II) acetylacetonate in contrast promotes cyclopropanation at the more substituted double bond (equation 118)13. Regiocontrol in the cyclopropanation of norbornene derivative 133 is strongly catalyst-dependent (equation 119). When diphenyldiazomethane is used as carbenoid precursor, the regioselectivity of this cyclopropanation is significantly enhanced165. 

Copper(II) triflate—a Lewis acid that is stable in aqueous media—has been employed as a catalyst for a variety of aldol and allylation reactions.83... 

Unsaturated ethers. The efficient insertion of carboalkoxycarbenes into the O—H bond of alcohols catalyzed by Rh(II) acetate (5, 571-572) extends to reactions with unsaturated alcohols. For this reaction copper(II) triflate is usually comparable to rhodium(II) alkanoates. Insertion predominates over cyclopropanation in the case of ethylenic alcohols. In reactions with acetylenic alcohols, cyclopropenation can predominate over insertion because of steric effects, as in reactions of HC=CC(CH3)2OH where the insertion/addition ratio is 36 56. 

In addition to these commonplace substrates, only a few extraordinary educts have been used in iron-catalyzed DA reactions, such as the naphthoquinones investigated by Brimble and McEwen [75]. Whereas the application of FeCl3 and a chiral bisoxazoline ligand gave only a 25% yield and no chiral induction in the reaction of 2-acetyl-l,4-naphthoquinone with cyclopentadiene, the corresponding copper(II) triflate gave a 66% yield and moderate enantioselectivities (up to 50% ee). Another example was reported by Shibasaki s group in which the 2-alkoxy-l,3-butadiene 40... 

With this end in view, phenyldimcthylsilyl tri-n-butylstannane was added under the influence of zero-valent palladium compound with high regioselectivity and in excellent yield to the acetylene 386 to give the metallated olefin 387 (Scheme 56). The vinyl lithium carbanion 388 generated therefrom, was then converted by reaction with cerium(lll) chloride into an equilibrium mixture (1 1) of the cerium salts 389 and 390 respectively. However, the 1,2-addition of 389 to the caibonyl of 391, which in principle would have eventually led to ( )-pretazettine, did not occur due to steric reasons — instead, only deprotonation of 391 was observed. On the other hand, 390 did function as a suitable nucleophile to provide the olefinic product 392. Exposure of 392 to copper(II) triflate induced its transformation via the nine membered enol (Scheme 55) to the requisite C-silyl hydroindole 393. On treatment with tetrafluoroboric acid diethyl ether complex in dichloromethane, compound 393 suffered... 

The influence of Lewis acids on the 4 + 2-cycloaddition of (2ft,2/ft)-A,iV/-fumaro-ylbis[fenchane-8,2-sultam] with cyclopentadiene and cyclohexadiene was investigated by IR studies of the sultam compexes with various Lewis acids.101 The first enantios-elective silicon Lewis acid catalyst (91) catalysed the Diels-Alder cycloaddition of methacrolein and cyclopentadiene with 94% ee.102 [A1C13 + 2THF] is a new and efficient catalytic system for the Diels-Alder cycloaddition of a,/9-unsaturated carbonyl compounds with dienes under solvent-free conditions.103 Dendritic copper(II) triflate catalysts with a 2,2 -bipyridine core (92) increased the chemical yields of Diels-Alder adducts.104... 

Chiral ferrocenoylpyrrolidines catalyse the highly enantioselective addition of dieth-ylzinc to iV-sulfonylimines in the presence of copper(II) triflate.47... 

A-Tosyl aldimines, RCH=N-Ts, add regioselectively to the C(2) of pyrroles, to give pyrrole sulfonamides (11), using copper(II) triflate as catalyst.53... 

The Boyer reaction - a relative of the Schmidt process - involves 2-oxazoline formation from a 2-azidoethanol and an aldehyde (RCHO).282 Using a 2-aryl-2-azidoethanol, a 2-oxazoline product and its 3-isomer are obtained using BF3 catalysis. However, on using copper(II) triflate, an acetal, RCH[OCH2CH(Ph)N3]2, resulted. 

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