A fast XPS study of sulphate promoted propene decomposition over Pt{111}

Adam F. Lee; K. Wilson; Andrea Goldoni; Rosanna Larciprete; Silvano Lizzit

doi:10.1016/S0039-6028(02)01703-X

A fast XPS study of sulphate promoted propene decomposition over Pt{111}

Adam F. Lee, K. Wilson, Andrea Goldoni, Rosanna Larciprete, Silvano Lizzit

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

Abstract

SO₂ oxidation has been followed by Fast XPS over Pt{111}. Preadsorbed oxygen reduces the low temperature saturation coverage of SO2 with respect to the clean surface. Heating a mixed O₂/SO₂ adlayer results in efficient oxidation of both upright and flat-lying SO₂ molecules to surface-bound SO₄. Sulphate decomposes above room temperature liberating gas-phase SO₂ and SO₃. Propene adsorbs molecularly at 100 K over clean Pt{111} and dehydrogenates above 250 K to form a stable propylidyne adlayer, which in turn decomposes above 400 K to form graphitic carbon. Preadsorbed surface sulphate enhances the sticking probability of propene via formation of an alkyl-sulphate complex. Thermal decomposition of this complex accounts for low temperature propene combustion and is accompanied by atomic sulpur deposition. Propylidyne forms as on clean Pt but is less reactive undergoing partial oxidation above 450 K with residual surface oxygen.

Original language	English
Pages (from-to)	140-148
Number of pages	9
Journal	Surface science
Volume	513
Issue number	1
DOIs	https://doi.org/10.1016/S0039-6028(02)01703-X
Publication status	Published - Jul 2002

Keywords

x-ray photoelectron spectroscopy
alkenes
catalysis
surface chemical reaction

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title = "A fast XPS study of sulphate promoted propene decomposition over Pt{111}",

abstract = "SO2 oxidation has been followed by Fast XPS over Pt{111}. Preadsorbed oxygen reduces the low temperature saturation coverage of SO2 with respect to the clean surface. Heating a mixed O2/SO2 adlayer results in efficient oxidation of both upright and flat-lying SO2 molecules to surface-bound SO4. Sulphate decomposes above room temperature liberating gas-phase SO2 and SO3. Propene adsorbs molecularly at 100 K over clean Pt{111} and dehydrogenates above 250 K to form a stable propylidyne adlayer, which in turn decomposes above 400 K to form graphitic carbon. Preadsorbed surface sulphate enhances the sticking probability of propene via formation of an alkyl-sulphate complex. Thermal decomposition of this complex accounts for low temperature propene combustion and is accompanied by atomic sulpur deposition. Propylidyne forms as on clean Pt but is less reactive undergoing partial oxidation above 450 K with residual surface oxygen.",

keywords = "x-ray photoelectron spectroscopy, alkenes, catalysis, surface chemical reaction",

author = "Lee, {Adam F.} and K. Wilson and Andrea Goldoni and Rosanna Larciprete and Silvano Lizzit",

year = "2002",

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T1 - A fast XPS study of sulphate promoted propene decomposition over Pt{111}

AU - Lee, Adam F.

AU - Wilson, K.

AU - Goldoni, Andrea

AU - Larciprete, Rosanna

AU - Lizzit, Silvano

PY - 2002/7

Y1 - 2002/7

N2 - SO2 oxidation has been followed by Fast XPS over Pt{111}. Preadsorbed oxygen reduces the low temperature saturation coverage of SO2 with respect to the clean surface. Heating a mixed O2/SO2 adlayer results in efficient oxidation of both upright and flat-lying SO2 molecules to surface-bound SO4. Sulphate decomposes above room temperature liberating gas-phase SO2 and SO3. Propene adsorbs molecularly at 100 K over clean Pt{111} and dehydrogenates above 250 K to form a stable propylidyne adlayer, which in turn decomposes above 400 K to form graphitic carbon. Preadsorbed surface sulphate enhances the sticking probability of propene via formation of an alkyl-sulphate complex. Thermal decomposition of this complex accounts for low temperature propene combustion and is accompanied by atomic sulpur deposition. Propylidyne forms as on clean Pt but is less reactive undergoing partial oxidation above 450 K with residual surface oxygen.

AB - SO2 oxidation has been followed by Fast XPS over Pt{111}. Preadsorbed oxygen reduces the low temperature saturation coverage of SO2 with respect to the clean surface. Heating a mixed O2/SO2 adlayer results in efficient oxidation of both upright and flat-lying SO2 molecules to surface-bound SO4. Sulphate decomposes above room temperature liberating gas-phase SO2 and SO3. Propene adsorbs molecularly at 100 K over clean Pt{111} and dehydrogenates above 250 K to form a stable propylidyne adlayer, which in turn decomposes above 400 K to form graphitic carbon. Preadsorbed surface sulphate enhances the sticking probability of propene via formation of an alkyl-sulphate complex. Thermal decomposition of this complex accounts for low temperature propene combustion and is accompanied by atomic sulpur deposition. Propylidyne forms as on clean Pt but is less reactive undergoing partial oxidation above 450 K with residual surface oxygen.

KW - x-ray photoelectron spectroscopy

KW - alkenes

KW - catalysis

KW - surface chemical reaction

UR - http://www.scopus.com/inward/record.url?scp=0036644528&partnerID=8YFLogxK

U2 - 10.1016/S0039-6028(02)01703-X

DO - 10.1016/S0039-6028(02)01703-X

M3 - Article

AN - SCOPUS:0036644528

SN - 0039-6028

VL - 513

SP - 140

EP - 148

JO - Surface science

JF - Surface science

IS - 1

ER -

A fast XPS study of sulphate promoted propene decomposition over Pt{111}

Abstract

Keywords

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