Lithium Dicyclohexylamide in Transition-Metal-Free Fischer–Tropsch Chemistry

Lithium dicyclohexylamide (Cy2NLi) reacts with syn-gas or CO to generate transient intermediates with carbene character, which are capable of reacting further with CO or H2, effecting sequential C–C and C–H bond formations from CO or H2, thus providing a transition-metal-free avenue to the fundament...

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Published in	Journal of the American Chemical Society Vol. 143; no. 2; pp. 634 - 638
Main Authors	Xu, Maotong, Qu, Zheng-wang, Grimme, Stefan, Stephan, Douglas W
Format	Journal Article
Language	English
Published	United States American Chemical Society 20.01.2021
Subjects	carbenes Fischer-Tropsch reaction lithium thermodynamics
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Abstract	Lithium dicyclohexylamide (Cy2NLi) reacts with syn-gas or CO to generate transient intermediates with carbene character, which are capable of reacting further with CO or H2, effecting sequential C–C and C–H bond formations from CO or H2, thus providing a transition-metal-free avenue to the fundamental reactions of the Fischer–Tropsch process. Further experimental and computational data indicate that reactions with CO and H2 are thermodynamically accessible, with a kinetic bias toward CO homologation.
AbstractList	Lithium dicyclohexylamide (Cy2NLi) reacts with syn-gas or CO to generate transient intermediates with carbene character, which are capable of reacting further with CO or H2, effecting sequential C–C and C–H bond formations from CO or H2, thus providing a transition-metal-free avenue to the fundamental reactions of the Fischer–Tropsch process. Further experimental and computational data indicate that reactions with CO and H2 are thermodynamically accessible, with a kinetic bias toward CO homologation. Lithium dicyclohexylamide (Cy₂NLi) reacts with syn-gas or CO to generate transient intermediates with carbene character, which are capable of reacting further with CO or H₂, effecting sequential C–C and C–H bond formations from CO or H₂, thus providing a transition-metal-free avenue to the fundamental reactions of the Fischer–Tropsch process. Further experimental and computational data indicate that reactions with CO and H₂ are thermodynamically accessible, with a kinetic bias toward CO homologation. Lithium dicyclohexylamide (Cy2NLi) reacts with syn-gas or CO to generate transient intermediates with carbene character, which are capable of reacting further with CO or H2, effecting sequential C-C and C-H bond formations from CO or H2, thus providing a transition-metal-free avenue to the fundamental reactions of the Fischer-Tropsch process. Further experimental and computational data indicate that reactions with CO and H2 are thermodynamically accessible, with a kinetic bias toward CO homologation.Lithium dicyclohexylamide (Cy2NLi) reacts with syn-gas or CO to generate transient intermediates with carbene character, which are capable of reacting further with CO or H2, effecting sequential C-C and C-H bond formations from CO or H2, thus providing a transition-metal-free avenue to the fundamental reactions of the Fischer-Tropsch process. Further experimental and computational data indicate that reactions with CO and H2 are thermodynamically accessible, with a kinetic bias toward CO homologation. Lithium dicyclohexylamide (Cy NLi) reacts with syn-gas or CO to generate transient intermediates with carbene character, which are capable of reacting further with CO or H , effecting sequential C-C and C-H bond formations from CO or H , thus providing a transition-metal-free avenue to the fundamental reactions of the Fischer-Tropsch process. Further experimental and computational data indicate that reactions with CO and H are thermodynamically accessible, with a kinetic bias toward CO homologation.
Author	Xu, Maotong Qu, Zheng-wang Stephan, Douglas W Grimme, Stefan
AuthorAffiliation	Department of Chemistry Mulliken Center for Theoretical Chemistry, Institut für Physikalische und Theoretische Chemie
AuthorAffiliation_xml	– name: Mulliken Center for Theoretical Chemistry, Institut für Physikalische und Theoretische Chemie – name: Department of Chemistry
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Snippet	Lithium dicyclohexylamide (Cy2NLi) reacts with syn-gas or CO to generate transient intermediates with carbene character, which are capable of reacting further... Lithium dicyclohexylamide (Cy NLi) reacts with syn-gas or CO to generate transient intermediates with carbene character, which are capable of reacting further... Lithium dicyclohexylamide (Cy₂NLi) reacts with syn-gas or CO to generate transient intermediates with carbene character, which are capable of reacting further...
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Title	Lithium Dicyclohexylamide in Transition-Metal-Free Fischer–Tropsch Chemistry
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