Temperature Dual Enantioselective Control in a Rhodium-Catalyzed Michael-Type Friedel-Crafts Reaction: A Mechanistic Explanation

Temperature Dual Enantioselective Control in a Rhodium-Catalyzed Michael-Type Friedel-Crafts Reaction: A Mechanistic Explanation

By changing the temperature from 283 to 233 K, the S (99 % ee) or R (96 % ee) enantiomer of the Friedel–Crafts (FC) adduct of the reaction between N‐methyl‐2‐methylindole and trans‐β‐nitrostyrene can be obtained by using (SRh,RC)‐[(η5‐C5Me5)Rh{(R)‐Prophos}(H2O)][SbF6]2 as the catalyst precursor. Thi...

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Published in:Chemistry : a European journal Vol. 22; no. 31; pp. 11064 - 11083
Main Authors: Méndez, Isabel, Rodríguez, Ricardo, Polo, Víctor, Passarelli, Vincenzo, Lahoz, Fernando J., García-Orduña, Pilar, Carmona, Daniel
Format: Journal Article
Language:English
Published: Germany Blackwell Publishing Ltd 25-07-2016
Wiley Subscription Services, Inc
Subjects:
Adducts
Antipodes
asymmetric catalysis
Catalysis
Catalysts
Coordination compounds
Enantiomers
enantioselectivity
Friedel-Crafts reaction
Friedel-Crafts reactions
Kinetics
Mathematical analysis
Metals
NMR
Nuclear magnetic resonance
Precursors
Reaction kinetics
reaction mechanisms
Reaction time
Rhodium
Temperature
Temperature effects
Friedel-Crafts reactions
enantioselectivity
reaction mechanisms
asymmetric catalysis
rhodium
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Summary:By changing the temperature from 283 to 233 K, the S (99 % ee) or R (96 % ee) enantiomer of the Friedel–Crafts (FC) adduct of the reaction between N‐methyl‐2‐methylindole and trans‐β‐nitrostyrene can be obtained by using (SRh,RC)‐[(η5‐C5Me5)Rh{(R)‐Prophos}(H2O)][SbF6]2 as the catalyst precursor. This catalytic system presents two other uncommon features: 1) The ee changes with reaction time showing trends that depend on the reaction temperature and 2) an increase in the catalyst loading results in a decrease in the ee of the S enantiomer. Detection and characterization of the intermediate metal–nitroalkene and metal–aci‐nitro complexes, the free aci‐nitro compound, and the FC adduct‐complex, together with solution NMR measurements, theoretical calculations, and kinetic studies have allowed us to propose two plausible alternative catalytic cycles. On the basis of these cycles, all the above‐mentioned observations can be rationalized. In particular, the reversibility of one of the cycles together with the kinetic resolution of the intermediate aci‐nitro complexes account for the high ee values achieved in both antipodes. On the other hand, the results of kinetic measurements explain the unusual effect of the increment in catalyst loading. This way or that? Two enantiomers (up to 99 % ee each) of the corresponding Friedel–Crafts adducts can be selectively accessed from the reaction between N‐methyl‐2‐methylindole and trans‐β‐nitrostyrene by using (SRh,RC)‐[(η5‐C5Me5)Rh{(R)‐Prophos}(H2O)][SbF6]2 as the catalyst precursor by simply changing the reaction temperature (see figure). A rationale is put forward for this behavior that includes the operation of two alternative catalytic cycles.
Bibliography:ark:/67375/WNG-7MWHSQ23-4
European Social Fund
ArticleID:CHEM201601301
CONSOLIDER INGENIO-2010 - No. CSD2006-0015
CSIC
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istex:BCC1A0D46C7E223BC183D655ED78649BF99268C7
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ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0947-6539
1521-3765
DOI:10.1002/chem.201601301