Secciones
Referencias
Resumen
Fuente
Cómo citar
Buscar
Reactions of alkenes and alkynes with formaldehyde catalyzed by rhodium systems containing phosphine ligands

Journal of the Mexican Chemical Society, vol. 61, no. 2, 2017

Sociedad Química de México A.C.

Merlín Rosales, *

Universidad del Zulia, Venezuela

Beatriz González

Universidad del Zulia, Venezuela

Jessely Molina

Universidad del Zulia, Venezuela

Homero Pérez

Universidad del Zulia, Venezuela

María Modroño-Alonso

Universidad de Carabobo, Venezuela

Pablo J. Baricelli

Universidad de Carabobo, Venezuela

Date received: 18 October 2016

Date accepted: 08 March 2017

Abstract.: The reaction of alkenes (allyl alcohol, styrene and C6 alkenes) with formaldehyde was efficiently performed by using Rh precatalysts formed in situ by the addition of triphenylphosphine (PPh3), 1,2-bis(diphenylphosphino)ethane (dppe) or 1,1,1-tris(diphenylphosphinomethyl)ethane (triphos) to the complex Rh(acac)(CO)2 at 130ºC in 1,4-dioxane, yielding their corresponding aldehydes; the best catalytic system was Rh(acac)(CO)2/2dppe, which generates the cationic complex [Rh(κ2-P,P-dppe)2]+. However, the reaction of phenylacetylene with formaldehyde under the same reaction conditions generated styrene, which was found to be the product of transfer hydrogenation from formaldehyde.

Keywords: hydroformylation, formaldehyde, alkenes, alkynes, rhodium, phosphine.

Resumen.: La reacción de alquenos (alcohol alílico, estireno y alquenos C6) con formaldehido se realizó eficientemente usando precatalizadores de Rh formados in situ por adición de trifenilfosfina (PPh3), 1,2-bis(difenilfosfino)etano (dffe) o 1,1,1-tris(difenilfosfinometil) etano (trifos) al complejo Rh(acac)(CO)2 a 130ºC en 1,4-dioxano, produciendo los correspondientes aldehídos. El mejor sistema catalítico fue Rh(acac)(CO)2/2dffe, el cual genera el complejo catiónico [Rh(κ2-P,P-dffe)2]+. Sin embargo, la reacción de fenilacetileno con formaldehido bajo las mismas condiciones de reacción generó estireno, el cual es el producto de la transferencia de hidrógeno del formaldehido.

Palabras clave: hidroformilación, formaldehido, alquenos, alquinos, rodio, fosfina.

Introduction

The hydroformylation of unsaturated substrates (alkenes, dienes and alkynes) is a well known synthetic tool for the synthesis of a wide range of organic molecules of high commercial value and it is also one of the largest industrial scale applications of organometallic catalysis for the manufacture of aldehydes and/or alcohols [1-4]. All industrial hydroformylation processes make use of highly toxic and flammable syn-gas (CO and H2 mixture), which has restricted somehow the widely use of hydroformylation in industry and academia. Hence, performing hydroformylation without the use of syn-gas is highly desired and will contribute to the further advancement of sustainable chemistry. Formaldehyde, either in solution (formalin) or as solid (paraformaldehyde), is one of the surrogates for syn-gas in hydroformylation reactions [5].

However, the version of hydroformylation of alkenes with formaldehyde has received very little attention since the first report of Okano et at. [6] in 1982. In the following three decades, the hydroformylation of unsaturated substrates with formaldehyde has been reported intermittently [7-11] and only recently this area has attracted significant interest, as emphasized by Franke et al. [12] in a review on the hydroformylation reaction and its applications. In fact, some of us reported the potential of rhodium catalysts containing triphenylphosphine (PPh3), diphosphines [Ph2P(CH2)nPPh2; n = 2, 3 and 4] and 1,1,1-tris(diphenylphosphino)ethane (triphos) in the hydroformylation with formaldehyde of 1-hexene (Eq. 1) and other C6 alkenes; the system Rh(acac)(CO)2/2dppe [dppe: 1,2-bis(diphenylphosphino)ethane] was the most active precatalyst [13,14]. Morimoto et al. [15] reported the highly linear regioselective hydroformylation of 1-alkenes using formaldehyde to give aldehydes by using two rhodium catalysts: Rh2Cl2(binap)2 [binap: 2,2’-bis(diphenylphosphino)-1,1’-binaphthyl] and RhH(CO)2(xantphos) [xantphos: 4,5-bis(diphenylphosphino)-9,9-dimethylxanthene]. Taddei et al. [16] showed that this reaction may be accelerated under microwave dielectric heating. Other recent works on the reaction of alkenes, dienes and alkynes with formaldehyde have been also reported [17-23].

There are two possible pathways for the metal-catalyzed hydroformylation of alkenes with formaldehyde (Fig. 1), which proceed through the formation of a hydride-formyl complex, M(H)(CHO): i) the classical hydroformylation mechanism (path A), which consists in the decarbonylation of the hydride-formyl intermediate to give either a dihydride-carbonyl intermediate or syn-gas, with the subsequent traditional alkene hydroformylation catalyzed by either the same or other precatalyst, and ii) the hydroacylation mechanism (path B), which occurs by alkene insertion into the M-H bond and the reductive elimination of alkyl and formyl ligands.


Fig. 1
Possible pathways for the catalytic hydroformylation of alkenes with formaldehyde.

Morimoto et al. [15] demonstrated that the hydroformylation of 1-alkenes proceeds through the formaldehyde decomposition to give syn-gas catalyzed by a rhodium-binap complex and the posterior classical alkene hydroformylation catalyzed by Rh-xantphos one. More recently, some of us reported a detailed kinetic and mechanistic study of the hydroformylation of 1-hexene with formaldehyde (Eq. 1) catalyzed by [Rh(κ2-P,P-dppe)2]acac; experimental results and theoretical DFT calculations proportioned evidences on favor of a hydroacylation mechanism [24].

(1)

In the present work, we disclose the use of rhodium precatalysts containing PPh3, dppe and triphos for the reaction of other unsaturated substrates (allyl alcohol, styrene and phenylacetylene) with formaldehyde, including some coordination chemistry studies; the initial rates of these reactions were also compared with the hydroformylation of C6 alkenes with formaldehyde.

Results and discussion

Catalytic reactions of unsaturated substrates with formaldehyde

The reaction of allyl alcohol, styrene and phenylacetylene with formaldehyde in 1,4-dioxane solution was studied using several rhodium systems, which were formed in situ by the reaction of the complex Rh(acac)(CO)2 with the corresponding equivalents of triphenylphosphine (PPh3), 1,2-bis(diphenylphosphino)ethane (dppe) and 1,1,1-tris(diphenylphosphinomethyl)ethane (triphos) at 130 °C.

In Table 1 are summarized the results of the hydroformylation of allyl alcohol (2-propen-1-ol) to produce 4-hydroxy-butanal and 2-methyl-3-hydroxypropanal, products that were identified for the molecular ion peaks at M+ 88, besides higher intensity peaks (base peaks) at m/z 42 and 57 u.m.a corresponding to the loss of 46 units (ethanol) and 31 units (methanol), respectively; propanal was also obtained (17-53% in 4 h), by isomerization of this substrate and subsequent tautomerization, as may be observed in Fig. 2.

Table 1
Hydroformylation of allyl alcohol with formaldehyde catalyzed by rhodium-phosphine systems


Fig. 2
Products of the catalytic reaction of allyl alcohol with formaldehyde.

Although the unmodified complex Rh(acac)(CO)2 was catalytically inactive for the hydroformylation of allyl alcohol with formaldehyde, the addition of PPh3, dppe and triphos to this complex did induce the formation of the corresponding aldehydes (TON varying from 24 to 195) at 130ºC. The highest activity (with the lowest percentage of isomerization-tautomerization to propanal) was obtained when two equivalents of dppe were added to Rh(acac)(CO)2 , which generates the cationic complex [Rh(κ2-P,P-dppe)2]+, as reported by Rosales et al. [13,14,24]. The catalytic activity of this system was four times higher than the activity generated by addition of 1 eq dppe, twice higher than those generated by addition of 2 or 3 eq. of PPh3 and eight times higher than that of the Rh/triphos system. Regioselectivities towards the corresponding linear aldehyde were from moderate to high, being the most selective system Rh/2 dppe ( l/b = 30). For comparison, under the same reaction conditions, the complex RhH(CO)(PPh3)3 displayed a good activity (36 TON in 4h) with high regioselectivity toward the linear aldehyde ( l/b = 21), results which are concordant with those reported by Seok et al. [11].

On the other hand, these systems were also active for the hydroformylation of styrene with formaldehyde (Eq. 2), under the same reaction conditions (see Table 2), obtaining the corresponding linear and branched aldehydes (3-phenyl- and 2-phenyl-propanal), which were identified by mass spectra (molecular ion peak M+ at m/z 134); small amounts of the hydrogenation product (ethylbenzene) were found (< 2%). The systems Rh/nPPh3 showed low activities (conversions lower than 10%, TON in the range between 15 and 21, in 4 h), and also low regioselectivities toward the linear aldehyde ( l/b = 1.6-2.5). The system Rh/2dppe also showed the highest activity (TON = 144), although the regioselectivity was moderate ( l/b = 2.0). The production of appreciable amounts of the branched aldehyde (ca. 33%) in the reaction catalyzed by Rh/2dppe is of special interest for application to the highly enantioselective and regioselective asymmetric hydroformylation of vinylarenes (styrenes and naphthylethylenes) with formaldehyde, which could provide high added-value products such as non-steroidal anti-inflammatory drug intermediates [25].

(2)

Table 2
Hydroformylation of styrene with formaldehyde catalyzed by rhodium-phosphine systems.

The results obtained for the hydroformylation of allyl alcohol with formaldehyde catalyzed by rhodium systems containing phosphine ligands differ somewhat to those obtained for the reaction of 1-hexene [13, 14] and styrene with formaldehyde by using the same catalytic systems. In fact, for the hydroformylation of simple alkenes (1-hexene and styrene), the order of catalytic activity is Rh/2dppe > Rh/dppe > Rh/triphos > Rh/nPPh3, whereas for the hydroformylation of allyl alcohol (an alkene with oxygen atom in β position), the order is Rh/2dppe > Rh/nPPh3 > Rh/dppe > Rh/triphos. The higher activity of the Rh/nPPh3 systems for the hydroformylation of allyl alcohol compared with simple alkenes may be explained by the coordination of the OH group of the substrate to the metal center, which should hinder the decarbonylation of the formyl group; the coordination of OH group of the substrate to the metal center has been reported by Seok et al [11] for the hydroformylation of allyl alcohol and acrolein catalyzed by RhH(CO)(PPh3)3. Although the hydroformylation of alkenes with formaldehyde catalyzed by Rh/2dppe proceeds via hydroacylation mechanism [24], the reaction catalyzed by Rh/nPPh3 and Rh/1dppe systems probably proceeds through a classic mechanisms in view of experimental evidences obtained in the coordination chemistry reported in the present work (vide infra). In fact, the Rh/3PPh3 system is a more active precatalyst than Rh/dppe one for the alkene hydroformylation under syngas conditions.

For comparative effects, Table 3 shows the measured reaction rates for the hydroformylation with formaldehyde of some olefins catalyzed by [Rh(dppe)2]acac, the most active precatalyst. 3,3-Dimethylbut-1-ene and 2,3-dimethylbut-1-ene were hydroformylated exclusively to their corresponding linear products (4,4- and 3,4-dimethylpentanal, respectively), presumably due to steric impediments for the formation of the branched alkyl intermediates. As may be observed, the simple alkenes without steric effect (3,3-dimethyl-1-butene and 1-hexene) were hydroformylated faster than 2,3-dimehyl-1-butene at 100ºC, whereas styrene (vinyl arene), allyl alcohol (alkene with an oxygen in β position) and cyclohexene (cyclic alkene) require a higher temperature (130ºC). Finally, the internal alkene, 2,3-dimehyl-2-butene, was not hydroformylated under these reaction conditions due to steric hindrance. The order of reactivity of these alkenes is:

Table 3
Comparison of reaction rates for the olefin hydroformylation with formaldehyde catalyzed by [Rh(dppe)2]acac.

On the other hand, the l/b ratio was moderate for 1-hexene and styrene ( l/b = 1.7 and 2.0, respectively) whereas a highly linear regioselective hydroformylation was observed for allyl alcohol susbtrate ( l/b = 30). These results are interesting because the system Rh/2dppe catalyzes the hydroformylation with formaldehyde of either simple alkenes (aliphatic and cyclic alkenes and vinylarenes) or alkenes containing oxygen at the β position to the carbon-carbon double bond, contrary to the results obtained by Seok et al. [11], who found that the complex RhH(CO)(PPh3)3 was more active for the hydroformylation with formaldehyde of alkenes containing oxygen at the β position to the carbon-carbon double bond than for simple alkenes, for which lower activities were found.

Finally, the reaction of phenylacetylene with formaldehyde catalyzed by Rh/phosphine systems, under the same reaction conditions (130 °C, 4h), did not generate the corresponding unsaturated aldehydes (3-phenyl- and 2-phenyl-propenal). Instead, styrene was almost quantitatively obtained in these reactions in 4 h, which may be the product of hydrogen transfer product of the formaldehyde or from the 1,4-dioxane solvent [26]. To demonstrate this, the same reactions were carried out in absence of formaldehyde; under these conditions phenylacetylene was not hydrogenated, which indicates that the hydrogenation of this substrate proceeds through decomposition of formaldehyde [27] and hydrogen transfer toward the metal center yielding rhodium-dihydride species and subsequently from rhodium to phenylacetylene.

Reactions of the Rh/dppe systems with formaldehyde

In order to gain further understanding on the mechanism of hydroformylation of unsaturated substrates with formaldehyde, the interaction of Rh(acac)(CO)2 with dppe and formaldehyde was studied; the results are shown in Fig. 3. In previous works, we have reported that reaction of the dicarbonylrhodium complex with 2 equivalents of dppe in 1,4-dioxane solution under reflux produces the cationic complex [Rh(κ2-P,P-dppe)2]+ (1), as its acetylacetonate (acac) salt [13, 14]; coordination chemistry and theoretical DFT studies followed us to propose that complex 1 is the active catalytic species. When the reaction of this complex with an excess of formaldehyde ([CH2O]/[Rh] = 10) was carried out, it was impossible to detect any other species different than the cationic bis(dppe)rhodium complex [24]. We considered that the cationic bis(dppe)rhodium complex reacted reversibly with formaldehyde to produce [RhH(CHO)(κ2-P,P-dppe)2]+ (2), which in absence of an unsaturated substrate (alkene or alkyne) come back to 1. Now, we performed these reactions by using only one equivalent of dppe. When the reaction of Rh(acac)(CO)2 with 1 equivalent of dppe was carried out, the presence of complex [Rh(κ2-P,P-dppe)2]+ (approximately 50 %) was observed as the only phosphorous complex; in some reactions, a small amount of a carbonyl complex was detected by IR (υCO in 1960 cm-1), which is probably Rh(acac)(CO)(κ1-P-dppe) (3) by comparison with the triphenylphosphine analogue complex, namely Rh(acac)(CO)(PPh3) [28]. The same reaction in the presence of an excess of formaldehyde mainly produces a mixture of two carbonyl complexes, as detected by IR (υCO = 2100, 2055 and 2010 cm-1) and 31P{1H} NMR, a monocarbonyl complex, possibly [Rh(CO)(1,4-dioxane)(κ2-P,P-dppe)]+ (4), and small amounts of the dicarbonyl one, namely [Rh(CO)22-P,P-dppe)]+ (5). The monocarbonyl complex (υCO = 2010 cm-1) showed in the 31P{1H} NMR spectrum two doublets of doublets (dd) centered at 67.0 and 66.9 ppm with coupling constants 1 J Rh-P = 131 Hz and 2 J P-P = 12 Hz, whereas the dicarbonyl complex (υCO = 2100 and 2055 cm-1) showed a doublet at 67.0 ppm [ 1 J Rh-P = 155 Hz]. Complex 4 may be formed from 3 by dissociation of an acac ligand and the subsequent coordination of both the other arm of dppe ligand as well as of a molecule of 1,4-dioxane, whereas complex 5 may be obtained by the reaction of 4 with formaldehyde to produce initially a hydride-formyl intermediate, [RhH(CHO)(CO)(κ2-P,P-dppe)]+, which suffers decarbonylation to generate a dihydride-dicarbonyl complex and finally the reductive elimination of dihydrogen. Fairlie and Bosnich [29] reported the synthesis of the ClO4 salt of complex 5, as well as similar complexes related to 4, namely [Rh(CO)(ketone)(κ2-P,P-dppe)]ClO4 (ketone: acetone and cyclopentanone).


Fig. 3
Reactions of Rh(acac)(CO)2 with dppe and formaldehyde.

These results indicate that in presence of one equivalent of dppe, the rhodium- catalyzed hydroformylation with formaldehyde probably proceed through a classical mechanism via formaldehyde decomposition. Perhaps, the hydroformylation of alkenes with formaldehyde employing the Rh/nPPh3 catalytic systems occurs through of a similar route than the Rh/dppe-catalyzed reaction.

Mechanistic proposal for the reactions of unsaturated substrates with formaldehyde

On the basis of experimental findings and the present knowledge of these reactions [15,24], we propose a plausible general mechanism for the reaction of the different substrates (alkenes and alkynes) with formaldehyde catalyzed by rhodium-phosphine systems, which is shown in Fig. 4. The catalytic cycle is initiated with the oxidative addition of formaldehyde C-H bond to generate a hydride-formyl rhodium species, which we suppose is the key intermediate of both cycles. For hydroformylation of alkenes with Rh/2dppe system, the following steps are the insertion of olefin into the Rh-H bond to generate an alkyl-formyl species and, finally, the reductive elimination of the corresponding aldehydes to regenerate the active species and restart the cycle; when Rh/dppe or Rh/nPPh3 systems are used as precatalysts, the reaction occurs probably through a classical hydroformylation mechanism (see Fig. 1). On the other hand, if the substrate is phenylacetylene, the hydride-formyl species suffers the decarbonylation of the formyl group to yield a dihydro-carbonyl species; substitution of CO ligand by phenylacetylene followed by the subsequent hydride transfer toward one of the carbon atom containing the triple bond and the reductive elimination of styrene completes the catalytic hydrogenation cycle.


Fig. 4
Proposed catalytic cycle for the reaction of alkenes and alkynes with formaldehyde catalyzed by rhodium-phosphine systems.

Conclusions

The hydroformylation of the carbon-carbon double bond of allyl alcohol and styrene was performed with formaldehyde by using rhodium-phosphine precatalysts in dioxane at 130 °C. The best system was that formed in situ by addition of 2 eq of dppe to the complex Rh(acac)(CO)2, yielding the cationic species [Rh(κ2-P,P-dppe)2]+, which displayed the highest activity. However, the reaction of phenylacetylene with formaldehyde under the same reaction conditions did generate styrene, which is the product of hydrogen transfer from the formaldehyde.

Experimental Section

Chemicals

Substrates (1-hexene, allyl alcohol, styrene, 3,3-dimethyl-1-butene, 2,3-dimethyl-1-butene, 2,3-dimethyl-2-butene and phenylacetylene) and the catalytic reaction solvent [1,4-dioxane (Riedel de Haens)] were purified by known procedures and distillated at reduced pressure before using [30]. CDCl3 (Aldrich) was dried using activated molecular sieves. Other chemicals [RhCl3.xH2O, PPh3, dppe and triphos (Stream Chemicals) and paraformaldehyde (Aldrich)] and solvents [toluene (Riedel de Haens), cycloheptane, ethylacetate and n-pentane (Merck)] were used as received.

General procedure

All manipulations were conducted with the rigorous exclusion of air using a vacuum line, an argon-filled Schlenk line and/or an argon-filled glovebox. Complex Rh(acac)(CO)2 was prepared from RhCl3.xH2O by a published procedure [28] whereas formaldehyde was generated in situ in the reaction medium dissolving paraformaldehyde in 1,4-dioxane.

Physical measurements

The products of the catalytic reactions were analyzed by GC using a 3300 Series VARIAN instrument fitted with a flame ionization detector (FID) and a 2 m 20 % SP-2100 on a 0.1 % carbowax 100/120 Supelcoport column, using N2 as carrier gas; the results were quantified with a VARIAN 4400 microcomputer. The products were additionally analyzed by a GC/MS HP 5890/5971 coupled system using a Quadrex PONA 5% phenyl methyl silicone, 25m, 320 μm column. Cycloheptane, ethyl acetate and toluene were used as internal standards for the reactions of C6 alkenes, allyl alcohol and styrene and phenylacetylene, respectively. The IR spectra (in KBr disk) were recorded on a Shimadzu 8300 FT-IR instrument. 31P{1H}-NMR spectra were recorded on a Bruker AM-300 spectrometer; chemical shift are expressed in p.p.m. upfield from H3PO4.

Catalytic reactions

The catalytic reactions were performed in a Fischer Porter reactor, in which a solution of Rh(acac)(CO)2 (0.05 mmol), the required amount of the corresponding phosphine, the substrate (15 mmol), formaldehyde (1.125 g, 40 mmol), the corresponding internal standard (8.3 mmol) and 1,4-dioxane (total volume 15 mL) were placed in the reactor. The system was flushed three times with argon and then heated to the desired reaction temperature; after 4 h with constant stirring, the system was cooled in ice. At the end of the catalytic reactions, the products were analyzed by GC.

Measurements of the initial rate of reactions

In order to measure the initial rate of the hydroformylation of olefins with formaldehyde, all the runs were performed at low conversions [31], by using a Parr Instrument high-pressure reactor. This reactor was provided with an arrangement for sampling of liquid contents, besides of automatic temperature, pressure and variable stirrer speed controls. In a typical experiment, a solution of the catalytic system, the corresponding substrate, formaldehyde, the internal standard (8.3 mmol) and 1,4-dioxane (total volume 30 mL) was placed in the reactor. The solution was deoxygenated and charged with argon at atmospheric pressure and the reactor was heated to the desired temperature. Aliquots of the reaction mixture were taken at regular intervals of time, which were monitored by using GC.

The data of the reactions were plotted as molar concentration of the products versus time in seconds yielding straight lines, which were fitted by conventional linear regression programs (r2 > 0.95); initial rates of the reaction ( r i ) were obtained from the corresponding slopes.

Reactions of Rh(acac)(CO) 2 with dppe and formaldehyde

These reactions were performed by the interaction of Rh(acac)(CO)2 (103 mg, 0.4 mmol) with one (160 mg, 0.4 mmol) or two equivalents (320 mg, 0.8 mmol) of dppe in the presence or absence of a ten-fold excess of formaldehyde (120 mg, 4 mmol) in 1,4-dioxane (10 mL) under reflux for 2 h. The corresponding solution was evaporated until dryness and the solid was washed with n-pentane.

Acknowledments

We thank to División de Investigación of the Facultad Experimental de Ciencias and Consejo de Desarrollo Científico y Humanístico (CONDES) of the Universidad del Zulia (L.U.Z.) for finantial supports.

References

1.. 1. Van Leeuwen, P. C. J.; Claver, C., Eds., Rhodium catalyzed hydroformylation, Kluwer Academic Publishers, 2000.

2.. 2. Frohning, C.D.; Kohlpaintner, C.W.; Bohnen, H.-W., in: Applied Homogeneous Catalysis with Organometallic Compounds, Vol. 1, Cornils, B.; Herrmann, W.A., Eds., Wiley-VCH, Weinheim, 2002, 31-103.

3.. 3. Bhaduri, S.; Mukesh, D. Homogeneous Catalysis: Mechanisms and Industrial Applications. Wiley-Interscience, Ed. New York, 2014, 141-152.

4.. 4. Whiteker, G.T.; Cobley, C.J. Top Organometal. Chem. 2012, 42, 35-46.

5.. 5. Wu, L.; Liu, Q.; Jackstell, R.; Beller, M. Angew. Chem. Int. Ed. 2014, 53, 6310-6320.

6.. 6. Okano, T.; Kobayashi, T.; Konishi, H.; Kiji, J. Tetrahedron Lett. 1982, 23, 4967-4968.

7.. 7. Jenner, G.; Nahmed, E. M.; Libs-Konrath, S. J. Mol. Catal. 1991, 64, 337-347.

8.. 8. Aika, K.; Sekija, H.; Ozaki, A. C1 Mol. Chem. 1984, 1, 65-67.

9.. 9. Blackborow, J. R.; Daroda, R. J.; Wilkinson, G. Coord. Chem. Rev. 1982, 43, 17-38.

10.. 10. Lassaletta, J. M.; Fernández, R.; Gasch, C.; Vasquez, J. Tetrahedron 1996, 52, 9143-9160.

11.. 11. Ahn, H. S., Han, S. H.; Uhm, S. J.; Seok, W. K., Lee, H. N.; Korneeva, G. A. J. Mol. Catal. A: Chemical 1999, 144, 295-306.

12.. 12. Franke, B.; Selent, D.; Börner, A. Chem. Rev. 2012, 112, 5675-5732.

13.. 13. Rosales, M.; González, A.; González, B.; Moratinos, C.; Pérez, H.; Urdaneta, J.; Sánchez-Delgado, R. J. Organomet. Chem. 2005, 690, 3095-3098.

14.. 14. Rosales, M.; Arrieta, F.; González, A.; Baricelli, P. J., González, B.; Guerrero, Y.; Moratinos, C.; Pacheco, I.; Pérez, H.; Urdaneta, J. Catal. Lett. 2008, 126, 367-370.

15.. 15. Makado, G.; Morimoto, T.; Sugimoto, Y.; Tsutsumi, K.; Kagawa, N.; Kakiuchi, K. Adv. Synth. Catat. 2010, 352, 299-304.

16.. 16. Cini, E.; Airiau, E.; Girard, N.; Mann, A.; Salvadori, J.; Taddei, M. Synlett. 2011, 199-202.

17.. 17. Fuji, K.; Morimoto, T.; Tsusumi, K.; Kakiuchi, K. Angew. Chem. Int. Ed. 2003, 42, 2409-2411.

18.. 18. Fuji, K.; Morimoto, T.; Tsutsumi, K.; Kakiuchi, K. Tetrahedron Lett. 2004, 45, 9163-9166.

19.. 19. Fuji, K.; Morimoto, T.; Tsutsumi, K.; Kakiuchi, K. Chem. Commun. 2005, 3295-3297.

20.. 20. Morimoto, T.; Fujioka, M.; Fuji, K.; Tsutsumi, K.; Kakiuchi, K. J. Organomet. Chem. 2007, 692, 625-634.

21.. 21. Morimoto, T.; Yamasaki, K.; Hirano, A.; Tsutsumi, K.; Kagawa, N.; Kakiuchi, K.; Harada, Y.; Fukimoto, Y.; Chatani, N.; Nishioka, T. Org. Lett. 2009, 11, 1777-1780.

22.. 22. Uhlemann, M.; Doerfelt, S.; Börner, A. Tetrahedron Lett. 2013, 54, 2209.

23.. 23. Köpfer, A.; Sam, B.; Breit, B.; Krische, M. J. Chem. Sci. 2013, 4, 1876-1880.

24.. 24. Rosales, M.; Pérez, H.; Arrieta, F.; Izquierdo, R.; Moratinos, C.; Baricelli, P. J. J. Mol. Catal. A: Chemical 2016, 421, 122-130.

25.. 25. Nozaki, K., in: Comprehensive Assymetric Catalysis, Jacobsen, E. N.; Pfaltz, A.; Yamamoto, H., Eds., Springer-Verlag, Berlin, 1999.

26.. 26. Brtieger, G.; Nestrick, T. J. Chem. Rev. 1974, 74, 567-580.

27.. 27. Beck, C. M.; Rathmill, S. E.; Park, Y. J.; Chen, J.; Crabtree, R. H. Organometallics 1999, 18, 5311.

28.. 28. Varshavskii, Y. S.; Cherkasova, T. G. Russ. J. Inorg. Chem. (Engl. Transl) 1967, 12, 899.

29.. 29. Fairlie, D. P.; Bosnich, B. Organometallics 1988, 7, 946-954.

30.. 30. Perrin, D.; Armarego, W.L.F., Purification of Laboratory Chemicals, 3rd. Ed., Pergamon Press, Great Britain, 1988.

31.. 31. Casado, J.; López-Quintela, M.A.; Lorenzo-Barral, F.M., J. Chem. Educ. 1986 63, 450-455.

Author notes

*Corresponding author: Tel +584143602104 FAX +582614127701 Ciudad Universitaria. Módulo 2. Maracaibo. Venezuela e-mail adress: [email protected]; [email protected] (M. Rosales)

Buscar:
Ir a la Página
IR
APA
ISO 690-2
Harvard