Competitive reaction pathways for the gas-phase reactivity of [Me2AlNH2]3

Elena I. Davydova; Gernot Frenking; Alexey Y. Timoshkin

doi:10.1002/cphc.201402230

Competitive reaction pathways for the gas-phase reactivity of [Me₂AlNH₂]₃

Elena I. Davydova, Gernot Frenking, Alexey Y. Timoshkin

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Reaction energy profiles for [Me₂AlNH₂]₃ have been computationally explored by using density functional theory. Both intraand intermolecular methane elimination reactions, as well as Al - N bond-breaking pathways, were considered. The results show that the energy required for Al - N bond breaking in cyclic [Me₂AlNH₂]₃ is of the same order of magnitude as the activation energies for the first (limiting) step of methane elimination (for both mono- and bimolecular mechanisms). Thus, dissociative and associative reaction pathways are competitive. Low-temperature/high-pressure conditions will favor the bimolecular pathway, whereas at high temperatures, either intramolecular methane elimination or Al - N bond-breaking dissociative pathways will be operational.

Original language	English
Pages (from-to)	2774-2779
Number of pages	6
Journal	ChemPhysChem
Volume	15
Issue number	13
DOIs	https://doi.org/10.1002/cphc.201402230
State	Published - 1 Sep 2014
Externally published	Yes

Keywords

Aluminum
Chemical vapor deposition
Density functional calculations
Reaction mechanisms thermochemistry

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title = "Competitive reaction pathways for the gas-phase reactivity of [Me2AlNH2]3",

abstract = "Reaction energy profiles for [Me2AlNH2]3 have been computationally explored by using density functional theory. Both intraand intermolecular methane elimination reactions, as well as Al - N bond-breaking pathways, were considered. The results show that the energy required for Al - N bond breaking in cyclic [Me2AlNH2]3 is of the same order of magnitude as the activation energies for the first (limiting) step of methane elimination (for both mono- and bimolecular mechanisms). Thus, dissociative and associative reaction pathways are competitive. Low-temperature/high-pressure conditions will favor the bimolecular pathway, whereas at high temperatures, either intramolecular methane elimination or Al - N bond-breaking dissociative pathways will be operational.",

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author = "Davydova, {Elena I.} and Gernot Frenking and Timoshkin, {Alexey Y.}",

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T1 - Competitive reaction pathways for the gas-phase reactivity of [Me2AlNH2]3

AU - Davydova, Elena I.

AU - Frenking, Gernot

AU - Timoshkin, Alexey Y.

PY - 2014/9/1

Y1 - 2014/9/1

N2 - Reaction energy profiles for [Me2AlNH2]3 have been computationally explored by using density functional theory. Both intraand intermolecular methane elimination reactions, as well as Al - N bond-breaking pathways, were considered. The results show that the energy required for Al - N bond breaking in cyclic [Me2AlNH2]3 is of the same order of magnitude as the activation energies for the first (limiting) step of methane elimination (for both mono- and bimolecular mechanisms). Thus, dissociative and associative reaction pathways are competitive. Low-temperature/high-pressure conditions will favor the bimolecular pathway, whereas at high temperatures, either intramolecular methane elimination or Al - N bond-breaking dissociative pathways will be operational.

AB - Reaction energy profiles for [Me2AlNH2]3 have been computationally explored by using density functional theory. Both intraand intermolecular methane elimination reactions, as well as Al - N bond-breaking pathways, were considered. The results show that the energy required for Al - N bond breaking in cyclic [Me2AlNH2]3 is of the same order of magnitude as the activation energies for the first (limiting) step of methane elimination (for both mono- and bimolecular mechanisms). Thus, dissociative and associative reaction pathways are competitive. Low-temperature/high-pressure conditions will favor the bimolecular pathway, whereas at high temperatures, either intramolecular methane elimination or Al - N bond-breaking dissociative pathways will be operational.

KW - Aluminum

KW - Chemical vapor deposition

KW - Density functional calculations

KW - Reaction mechanisms thermochemistry

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Competitive reaction pathways for the gas-phase reactivity of [Me₂AlNH₂]₃

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