Selectivity and mechanism shifts in the reactions of acetaldehyde on oxidized and reduced TiO2(001) surfaces

Hicham Idriss; M A  Barteau

Selectivity and mechanism shifts in the reactions of acetaldehyde on oxidized and reduced TiO2(001) surfaces

Hicham Idriss, M A Barteau

Chemistry

University of Delaware

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

83 Citations (Scopus)

Abstract

Depending on the oxidation state of the TiO2(001) surface, acetaldehyde can form C-4 products by either aldol condensation or reductive coupling routes. Aldol condensation generates crotonaldehyde and crotyl alcohol, and is favored on oxidized, stoichiometric surfaces. Reductive coupling produces butene, and occurs only on reduced surfaces. The switch-over in selectivity with increasing extents of surface oxidation provides important insights into the active site requirements for each of these reactions.

Original language	English
Pages (from-to)	147-153
Number of pages	7
Journal	Catalysis Letters
Volume	40
Issue number	3-4
Publication status	Published - 1996

Keywords

acetaldehyde
butene
crotonaldehyde
aldol condensation
reductive carbonyl coupling
titanium dioxide
SINGLE-CRYSTAL SURFACES
CARBON BOND FORMATION
ALDOL CONDENSATION
OXIDE SURFACES
FORMALDEHYDE
ACID
ADSORPTION
REDUCTION
CATALYSTS

Cite this

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title = "Selectivity and mechanism shifts in the reactions of acetaldehyde on oxidized and reduced TiO2(001) surfaces",

abstract = "Depending on the oxidation state of the TiO2(001) surface, acetaldehyde can form C-4 products by either aldol condensation or reductive coupling routes. Aldol condensation generates crotonaldehyde and crotyl alcohol, and is favored on oxidized, stoichiometric surfaces. Reductive coupling produces butene, and occurs only on reduced surfaces. The switch-over in selectivity with increasing extents of surface oxidation provides important insights into the active site requirements for each of these reactions.",

keywords = "acetaldehyde, butene, crotonaldehyde, aldol condensation, reductive carbonyl coupling, titanium dioxide, SINGLE-CRYSTAL SURFACES, CARBON BOND FORMATION, ALDOL CONDENSATION, OXIDE SURFACES, FORMALDEHYDE, ACID, ADSORPTION, REDUCTION, CATALYSTS",

author = "Hicham Idriss and Barteau, {M A}",

year = "1996",

language = "English",

volume = "40",

pages = "147--153",

journal = "Catalysis Letters",

issn = "1011-372X",

publisher = "Springer Netherlands",

number = "3-4",

}

TY - JOUR

T1 - Selectivity and mechanism shifts in the reactions of acetaldehyde on oxidized and reduced TiO2(001) surfaces

AU - Idriss, Hicham

AU - Barteau, M A

PY - 1996

Y1 - 1996

N2 - Depending on the oxidation state of the TiO2(001) surface, acetaldehyde can form C-4 products by either aldol condensation or reductive coupling routes. Aldol condensation generates crotonaldehyde and crotyl alcohol, and is favored on oxidized, stoichiometric surfaces. Reductive coupling produces butene, and occurs only on reduced surfaces. The switch-over in selectivity with increasing extents of surface oxidation provides important insights into the active site requirements for each of these reactions.

AB - Depending on the oxidation state of the TiO2(001) surface, acetaldehyde can form C-4 products by either aldol condensation or reductive coupling routes. Aldol condensation generates crotonaldehyde and crotyl alcohol, and is favored on oxidized, stoichiometric surfaces. Reductive coupling produces butene, and occurs only on reduced surfaces. The switch-over in selectivity with increasing extents of surface oxidation provides important insights into the active site requirements for each of these reactions.

KW - acetaldehyde

KW - butene

KW - crotonaldehyde

KW - aldol condensation

KW - reductive carbonyl coupling

KW - titanium dioxide

KW - SINGLE-CRYSTAL SURFACES

KW - CARBON BOND FORMATION

KW - ALDOL CONDENSATION

KW - OXIDE SURFACES

KW - FORMALDEHYDE

KW - ACID

KW - ADSORPTION

KW - REDUCTION

KW - CATALYSTS

M3 - Article

SN - 1011-372X

VL - 40

SP - 147

EP - 153

JO - Catalysis Letters

JF - Catalysis Letters

IS - 3-4

ER -

Selectivity and mechanism shifts in the reactions of acetaldehyde on oxidized and reduced TiO2(001) surfaces

Abstract

Keywords

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