Internally Catalyzed Hydrogen Atom Transfer (<i>I-CHAT</i>)—A New Class of Reactions in Combustion Chemistry

Internally Catalyzed Hydrogen Atom Transfer (<i>I-CHAT</i>)—A New Class of Reactions in Combustion Chemistry

The current paradigm of low-T combustion and autoignition of hydrocarbons is based on the sequential two-step oxygenation of fuel radicals. The key chain-branching occurs when the second oxygenation adduct (OOQOOH) is isomerized releasing an OH radical and a key <i>ketohydroperoxide</i>...

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Bibliographic Details
Main Authors: Rubik Asatryan, Jason Hudzik, Venus Amiri, Mark T. Swihart
Format: Article
Language:English
Published: MDPI AG 2025-01-01
Series:Molecules
Subjects:
intramolecular catalysis
hydrogen atom transfer
dihydrogen catalysis
autoignition
chain-branching
ketohydroperoxides
Online Access:https://www.mdpi.com/1420-3049/30/3/524
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Summary:The current paradigm of low-T combustion and autoignition of hydrocarbons is based on the sequential two-step oxygenation of fuel radicals. The key chain-branching occurs when the second oxygenation adduct (OOQOOH) is isomerized releasing an OH radical and a key <i>ketohydroperoxide</i> (KHP) intermediate. The subsequent homolytic dissociation of relatively weak O–O bonds in KHP generates two more radicals in the oxidation chain leading to ignition. Based on the recently introduced intramolecular “catalytic hydrogen atom transfer” mechanism (<i>J. Phys. Chem.</i> 2024, <i>128</i>, 2169), abbreviated here as <i>I-CHAT</i>, we have identified a novel unimolecular decomposition channel for KHPs to form their classical isomers<i>—enol hydroperoxides</i> (EHP). The uncertainty in the contribution of enols is typically due to the high computed barriers for conventional (“direct”) keto–enol tautomerization. Remarkably, the <i>I-CHAT</i> dramatically reduces such barriers. The novel mechanism can be regarded as an <i>intramolecular</i> version of the <i>intermolecular</i> relay transfer of H-atoms mediated by an external molecule following the general classification of such processes (<i>Catal. Rev.-Sci. Eng.</i> 2014, <i>56</i>, 403). Here, we present a detailed mechanistic and kinetic analysis of the <i>I-CHAT</i>-facilitated pathways applied to <i>n</i>-hexane, <i>n</i>-heptane, and <i>n</i>-pentane models as prototype molecules for gasoline, diesel, and hybrid rocket fuels. We particularly examined the formation kinetics and subsequent dissociation of the γ-enol-hydroperoxide isomer of the most abundant pentane-derived isomer γ-C5-KHP observed experimentally. To gain molecular-level insight into the <i>I-CHAT</i> catalysis, we have also explored the role of the internal catalyst moieties using truncated models. All applied models demonstrated a significant reduction in the isomerization barriers, primarily due to the decreased ring strain in transition states. In addition, the longer-range and sequential H-migration processes were also identified and illustrated via a <i>combined double</i> keto–enol conversion of heptane-2,6-diketo-4-hydroperoxide as a potential chain-branching model. To assess the possible impact of the <i>I-CHAT</i> channels on global fuel combustion characteristics, we performed a detailed kinetic analysis of the isomerization and decomposition of γ-C5-KHP comparing <i>I-CHAT</i> with key alternative reactions—direct dissociation and Korcek channels. Calculated rate parameters were implemented into a modified version of the <i>n</i>-pentane kinetic model developed earlier using RMG automated model generation tools (<i>ACS Omega,</i> 2023, <i>8,</i> 4908). Simulations of ignition delay times revealed the significant effect of the new pathways, suggesting an important role of the <i>I-CHAT</i> pathways in the low-T combustion of large alkanes.
ISSN:1420-3049

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