Standard

A thermochemical ladder to biosynthetic fuels: from quantum chemistry downstairs to the liquid-phase energetics of eugenol hydrodeoxygenation as a model for lignin upgrading. / Verevkin, S.P.; Zasypalov, Gleb O.; Klimovsky, Vladimir A.; Pimerzin, Aleksey A.; Vutolkina, A.V.; Samarov, Artemiy A.; Vostrikov, Sergey; Metalnikova, Vera M.; Siewert, Riko; Müller, Karsten; Glotov, Aleksandr.

в: Chemical Engineering Journal, Том 521, 166609, 01.10.2025.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

Verevkin, SP, Zasypalov, GO, Klimovsky, VA, Pimerzin, AA, Vutolkina, AV, Samarov, AA, Vostrikov, S, Metalnikova, VM, Siewert, R, Müller, K & Glotov, A 2025, 'A thermochemical ladder to biosynthetic fuels: from quantum chemistry downstairs to the liquid-phase energetics of eugenol hydrodeoxygenation as a model for lignin upgrading.', Chemical Engineering Journal, Том. 521, 166609. https://doi.org/10.1016/j.cej.2025.166609

APA

Verevkin, S. P., Zasypalov, G. O., Klimovsky, V. A., Pimerzin, A. A., Vutolkina, A. V., Samarov, A. A., Vostrikov, S., Metalnikova, V. M., Siewert, R., Müller, K., & Glotov, A. (2025). A thermochemical ladder to biosynthetic fuels: from quantum chemistry downstairs to the liquid-phase energetics of eugenol hydrodeoxygenation as a model for lignin upgrading. Chemical Engineering Journal, 521, [166609]. https://doi.org/10.1016/j.cej.2025.166609

Vancouver

Verevkin SP, Zasypalov GO, Klimovsky VA, Pimerzin AA, Vutolkina AV, Samarov AA и пр. A thermochemical ladder to biosynthetic fuels: from quantum chemistry downstairs to the liquid-phase energetics of eugenol hydrodeoxygenation as a model for lignin upgrading. Chemical Engineering Journal. 2025 Окт. 1;521. 166609. https://doi.org/10.1016/j.cej.2025.166609

Author

Verevkin, S.P. ; Zasypalov, Gleb O. ; Klimovsky, Vladimir A. ; Pimerzin, Aleksey A. ; Vutolkina, A.V. ; Samarov, Artemiy A. ; Vostrikov, Sergey ; Metalnikova, Vera M. ; Siewert, Riko ; Müller, Karsten ; Glotov, Aleksandr. / A thermochemical ladder to biosynthetic fuels: from quantum chemistry downstairs to the liquid-phase energetics of eugenol hydrodeoxygenation as a model for lignin upgrading. в: Chemical Engineering Journal. 2025 ; Том 521.

BibTeX

@article{511c9d144d36463f851d2e0244c98607,
title = "A thermochemical ladder to biosynthetic fuels: from quantum chemistry downstairs to the liquid-phase energetics of eugenol hydrodeoxygenation as a model for lignin upgrading.",
abstract = "The valorisation of lignin is one of the current challenges for science and industry. Studies on eugenol as a model compound for hydrodeoxygenation considerably facilitate the understanding of the general trends in this complex reaction cascade. The thermochemical properties of the starting material eugenol, the end products (alkylcyclopentanes and alkylcyclohexanes) and the intermediate products of the network, which comprises 18 possible reactions, were evaluated. According to the quantitative thermodynamic analysis, none of the 18 reactions are subject to significant thermodynamic limitations. However, the final distribution of reaction products is determined by acidity, textural properties and active phase valence state at constant experimental conditions. Nevertheless, a quantitative understanding of thermodynamics is indispensable to evaluate the magnitude of the equilibrium constant at a particular temperature and to adjust the type and amount of catalyst, time and temperature and to obtain sufficient yields of biosynthetic fuel compounds. The thermodynamic investigation findings were corroborated through the empirical data. The highest selectivity to 2-methoxy-4-propylphenol (side chain hydrogenation) of 79 % over Ru/HNT with low acidity was observed. In contrast, for the Ru/HNT-t catalyst with enhanced Br{\o}nsted and Lewis acidity the major products were propylcyclohexane (42 %, complete hydrodeoxygenation) and 4-propylcyclohexanol (20 %, demethoxylation‑hydrogenation) at 180 °C. An increase in the temperature to 210 °C leads to the quantitative conversion of eugenol and an increase in propylcyclohexane selectivity for both catalysts (Ru/HNT – 38.2 %, Ru/HNT-t – 77.9 %). Other parallel routes are consistent with thermodynamic analysis performed in this work.",
keywords = "Лигнин, Гидродеоксигенация, Энтальпии фазовых переходов, Галлуазит, Энтальпия образования, Квантово-химические расчёты, Давление пара, Enthalpies of phase transitions, Enthalpy of formation, Halloysite, Hydrodeoxygenation, Lignin, Quantum-chemical calculations, Vapor pressure",
author = "S.P. Verevkin and Zasypalov, {Gleb O.} and Klimovsky, {Vladimir A.} and Pimerzin, {Aleksey A.} and A.V. Vutolkina and Samarov, {Artemiy A.} and Sergey Vostrikov and Metalnikova, {Vera M.} and Riko Siewert and Karsten M{\"u}ller and Aleksandr Glotov",
year = "2025",
month = oct,
day = "1",
doi = "10.1016/j.cej.2025.166609",
language = "English",
volume = "521",
journal = "Chemical Engineering Journal",
issn = "1385-8947",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - A thermochemical ladder to biosynthetic fuels: from quantum chemistry downstairs to the liquid-phase energetics of eugenol hydrodeoxygenation as a model for lignin upgrading.

AU - Verevkin, S.P.

AU - Zasypalov, Gleb O.

AU - Klimovsky, Vladimir A.

AU - Pimerzin, Aleksey A.

AU - Vutolkina, A.V.

AU - Samarov, Artemiy A.

AU - Vostrikov, Sergey

AU - Metalnikova, Vera M.

AU - Siewert, Riko

AU - Müller, Karsten

AU - Glotov, Aleksandr

PY - 2025/10/1

Y1 - 2025/10/1

N2 - The valorisation of lignin is one of the current challenges for science and industry. Studies on eugenol as a model compound for hydrodeoxygenation considerably facilitate the understanding of the general trends in this complex reaction cascade. The thermochemical properties of the starting material eugenol, the end products (alkylcyclopentanes and alkylcyclohexanes) and the intermediate products of the network, which comprises 18 possible reactions, were evaluated. According to the quantitative thermodynamic analysis, none of the 18 reactions are subject to significant thermodynamic limitations. However, the final distribution of reaction products is determined by acidity, textural properties and active phase valence state at constant experimental conditions. Nevertheless, a quantitative understanding of thermodynamics is indispensable to evaluate the magnitude of the equilibrium constant at a particular temperature and to adjust the type and amount of catalyst, time and temperature and to obtain sufficient yields of biosynthetic fuel compounds. The thermodynamic investigation findings were corroborated through the empirical data. The highest selectivity to 2-methoxy-4-propylphenol (side chain hydrogenation) of 79 % over Ru/HNT with low acidity was observed. In contrast, for the Ru/HNT-t catalyst with enhanced Brønsted and Lewis acidity the major products were propylcyclohexane (42 %, complete hydrodeoxygenation) and 4-propylcyclohexanol (20 %, demethoxylation‑hydrogenation) at 180 °C. An increase in the temperature to 210 °C leads to the quantitative conversion of eugenol and an increase in propylcyclohexane selectivity for both catalysts (Ru/HNT – 38.2 %, Ru/HNT-t – 77.9 %). Other parallel routes are consistent with thermodynamic analysis performed in this work.

AB - The valorisation of lignin is one of the current challenges for science and industry. Studies on eugenol as a model compound for hydrodeoxygenation considerably facilitate the understanding of the general trends in this complex reaction cascade. The thermochemical properties of the starting material eugenol, the end products (alkylcyclopentanes and alkylcyclohexanes) and the intermediate products of the network, which comprises 18 possible reactions, were evaluated. According to the quantitative thermodynamic analysis, none of the 18 reactions are subject to significant thermodynamic limitations. However, the final distribution of reaction products is determined by acidity, textural properties and active phase valence state at constant experimental conditions. Nevertheless, a quantitative understanding of thermodynamics is indispensable to evaluate the magnitude of the equilibrium constant at a particular temperature and to adjust the type and amount of catalyst, time and temperature and to obtain sufficient yields of biosynthetic fuel compounds. The thermodynamic investigation findings were corroborated through the empirical data. The highest selectivity to 2-methoxy-4-propylphenol (side chain hydrogenation) of 79 % over Ru/HNT with low acidity was observed. In contrast, for the Ru/HNT-t catalyst with enhanced Brønsted and Lewis acidity the major products were propylcyclohexane (42 %, complete hydrodeoxygenation) and 4-propylcyclohexanol (20 %, demethoxylation‑hydrogenation) at 180 °C. An increase in the temperature to 210 °C leads to the quantitative conversion of eugenol and an increase in propylcyclohexane selectivity for both catalysts (Ru/HNT – 38.2 %, Ru/HNT-t – 77.9 %). Other parallel routes are consistent with thermodynamic analysis performed in this work.

KW - Лигнин

KW - Гидродеоксигенация

KW - Энтальпии фазовых переходов

KW - Галлуазит

KW - Энтальпия образования

KW - Квантово-химические расчёты

KW - Давление пара

KW - Enthalpies of phase transitions

KW - Enthalpy of formation

KW - Halloysite

KW - Hydrodeoxygenation

KW - Lignin

KW - Quantum-chemical calculations

KW - Vapor pressure

UR - https://www.mendeley.com/catalogue/4e4b0d14-6bc1-3589-a6e3-3bb4930e3cb4/

U2 - 10.1016/j.cej.2025.166609

DO - 10.1016/j.cej.2025.166609

M3 - Article

VL - 521

JO - Chemical Engineering Journal

JF - Chemical Engineering Journal

SN - 1385-8947

M1 - 166609

ER -

ID: 143475205