Acrolein oxidation to acrylic acid over the MoVOx material. Insights from DFT modeling

Torstein Fjermestad; Wen qing Li; Graham Rugg; Satoshi Ishida; Masaaki Okuno; Kazuo Sagi; Alexander Genest; Notker Rösch

doi:10.1016/j.apcata.2018.07.044

Acrolein oxidation to acrylic acid over the MoVO_x material. Insights from DFT modeling

Torstein Fjermestad, Wen qing Li, Graham Rugg, Satoshi Ishida, Masaaki Okuno, Kazuo Sagi, Alexander Genest, Notker Rösch

Associate Professorship of Theoretical Chemistry (2008 — 2024)

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

15 Scopus citations

Abstract

MoVO_x-type catalysts are very active and very selective in the commercially important oxidation of acrolein to acrylic acid. To contribute to unravelling the thus far poorly understood mechanism, we carried out hybrid DFT calculations on embedded cluster models, focusing on the so-called pentameric unit as active site. In the absence of water, we calculated a large energy span, 169 kJ mol^–1, for this transformation. After addressing the hydrolysis of the surface, we examined four scenarios of the acrolein conversion to explore the effect of water. The most favorable variant has a notably lower energy span, 146 kJ mol^–1, in line with experimental observations that indicate a strong acceleration of the catalytic transformation in the presence of water.

Original language	English
Pages (from-to)	68-75
Number of pages	8
Journal	Applied Catalysis A: General
Volume	565
DOIs	https://doi.org/10.1016/j.apcata.2018.07.044
State	Published - 5 Sep 2018

Keywords

Acrolein
Acrylic acid
Catalyst
Hybrid DFT calculation
MoVO
Selective oxidation

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10.1016/j.apcata.2018.07.044

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title = "Acrolein oxidation to acrylic acid over the MoVOx material. Insights from DFT modeling",

abstract = "MoVOx-type catalysts are very active and very selective in the commercially important oxidation of acrolein to acrylic acid. To contribute to unravelling the thus far poorly understood mechanism, we carried out hybrid DFT calculations on embedded cluster models, focusing on the so-called pentameric unit as active site. In the absence of water, we calculated a large energy span, 169 kJ mol–1, for this transformation. After addressing the hydrolysis of the surface, we examined four scenarios of the acrolein conversion to explore the effect of water. The most favorable variant has a notably lower energy span, 146 kJ mol–1, in line with experimental observations that indicate a strong acceleration of the catalytic transformation in the presence of water.",

keywords = "Acrolein, Acrylic acid, Catalyst, Hybrid DFT calculation, MoVO, Selective oxidation",

author = "Torstein Fjermestad and Li, {Wen qing} and Graham Rugg and Satoshi Ishida and Masaaki Okuno and Kazuo Sagi and Alexander Genest and Notker R{\"o}sch",

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T1 - Acrolein oxidation to acrylic acid over the MoVOx material. Insights from DFT modeling

AU - Fjermestad, Torstein

AU - Li, Wen qing

AU - Rugg, Graham

AU - Ishida, Satoshi

AU - Okuno, Masaaki

AU - Sagi, Kazuo

AU - Genest, Alexander

AU - Rösch, Notker

PY - 2018/9/5

Y1 - 2018/9/5

N2 - MoVOx-type catalysts are very active and very selective in the commercially important oxidation of acrolein to acrylic acid. To contribute to unravelling the thus far poorly understood mechanism, we carried out hybrid DFT calculations on embedded cluster models, focusing on the so-called pentameric unit as active site. In the absence of water, we calculated a large energy span, 169 kJ mol–1, for this transformation. After addressing the hydrolysis of the surface, we examined four scenarios of the acrolein conversion to explore the effect of water. The most favorable variant has a notably lower energy span, 146 kJ mol–1, in line with experimental observations that indicate a strong acceleration of the catalytic transformation in the presence of water.

AB - MoVOx-type catalysts are very active and very selective in the commercially important oxidation of acrolein to acrylic acid. To contribute to unravelling the thus far poorly understood mechanism, we carried out hybrid DFT calculations on embedded cluster models, focusing on the so-called pentameric unit as active site. In the absence of water, we calculated a large energy span, 169 kJ mol–1, for this transformation. After addressing the hydrolysis of the surface, we examined four scenarios of the acrolein conversion to explore the effect of water. The most favorable variant has a notably lower energy span, 146 kJ mol–1, in line with experimental observations that indicate a strong acceleration of the catalytic transformation in the presence of water.

KW - Acrolein

KW - Acrylic acid

KW - Catalyst

KW - Hybrid DFT calculation

KW - MoVO

KW - Selective oxidation

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VL - 565

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EP - 75

JO - Applied Catalysis A: General

JF - Applied Catalysis A: General

ER -

Acrolein oxidation to acrylic acid over the MoVO_x material. Insights from DFT modeling

Abstract

Keywords

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