Lactose oxidation over palladium catalysts supported on active carbons and on carbon nanofibres

Anton V. Tokarev; Elena V. Murzina; Kari Eränen; Heidi Markus; Arie J. Plomp; Johannes H. Bitter; Päivi Mäki-Arvela; Dmitry Yu Murzin

doi:10.1007/s11164-008-0023-3

Lactose oxidation over palladium catalysts supported on active carbons and on carbon nanofibres

Anton V. Tokarev, Elena V. Murzina, Kari Eränen, Heidi Markus, Arie J. Plomp, Johannes H. Bitter, Päivi Mäki-Arvela, Dmitry Yu Murzin

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

14 Citations (Scopus)

Abstract

Liquid-phase lactose oxidation was investigated over supported Pd/C and Pd-carbon nanofibre catalysts, which were characterized by several methods. A complex relationship between catalyst activity and catalyst acidity was established, i.e. optimum catalyst acidity resulted in the highest activity in lactose oxidation. In-situ catalyst potential measurements during lactose oxidation gave information about the extent of accumulation of oxygen on the metal surface. These results could be correlated with catalyst deactivation, which was extensive over the most acidic catalysts at low reaction temperatures. Selectivity for the desired product, lactobionic acid, was a maximum of approximately 83% at 93% conversion. The main side-product was lactulose formed via isomerisation of lactose. Lower selectivity toward lactobionic acid was obtained when the rate of oxidation of lactose was low.

Original language	English
Pages (from-to)	155-174
Number of pages	20
Journal	Research on Chemical Intermediates
Volume	35
Issue number	2
DOIs	https://doi.org/10.1007/s11164-008-0023-3
Publication status	Published - Feb 2009
MoE publication type	A1 Journal article-refereed

Keywords

Active carbon
Carbon nanofibres
Catalyst potential
Lactose oxidation
Palladium
Surface acidity

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10.1007/s11164-008-0023-3

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title = "Lactose oxidation over palladium catalysts supported on active carbons and on carbon nanofibres",

abstract = "Liquid-phase lactose oxidation was investigated over supported Pd/C and Pd-carbon nanofibre catalysts, which were characterized by several methods. A complex relationship between catalyst activity and catalyst acidity was established, i.e. optimum catalyst acidity resulted in the highest activity in lactose oxidation. In-situ catalyst potential measurements during lactose oxidation gave information about the extent of accumulation of oxygen on the metal surface. These results could be correlated with catalyst deactivation, which was extensive over the most acidic catalysts at low reaction temperatures. Selectivity for the desired product, lactobionic acid, was a maximum of approximately 83% at 93% conversion. The main side-product was lactulose formed via isomerisation of lactose. Lower selectivity toward lactobionic acid was obtained when the rate of oxidation of lactose was low.",

keywords = "Active carbon, Carbon nanofibres, Catalyst potential, Lactose oxidation, Palladium, Surface acidity",

author = "Tokarev, {Anton V.} and Murzina, {Elena V.} and Kari Er{\"a}nen and Heidi Markus and Plomp, {Arie J.} and Bitter, {Johannes H.} and P{\"a}ivi M{\"a}ki-Arvela and Murzin, {Dmitry Yu}",

note = "Funding Information: Acknowledgements Financial support provided by the Academy of Finland within the Centre of Excellence Programme (2000–2011) and by the Graduate School in Chemical Engineering is gratefully acknowledged. Copyright: Copyright 2010 Elsevier B.V., All rights reserved.",

year = "2009",

month = feb,

doi = "10.1007/s11164-008-0023-3",

language = "English",

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pages = "155--174",

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AU - Tokarev, Anton V.

AU - Murzina, Elena V.

AU - Eränen, Kari

AU - Markus, Heidi

AU - Plomp, Arie J.

AU - Bitter, Johannes H.

AU - Mäki-Arvela, Päivi

AU - Murzin, Dmitry Yu

N1 - Funding Information: Acknowledgements Financial support provided by the Academy of Finland within the Centre of Excellence Programme (2000–2011) and by the Graduate School in Chemical Engineering is gratefully acknowledged. Copyright: Copyright 2010 Elsevier B.V., All rights reserved.

PY - 2009/2

Y1 - 2009/2

N2 - Liquid-phase lactose oxidation was investigated over supported Pd/C and Pd-carbon nanofibre catalysts, which were characterized by several methods. A complex relationship between catalyst activity and catalyst acidity was established, i.e. optimum catalyst acidity resulted in the highest activity in lactose oxidation. In-situ catalyst potential measurements during lactose oxidation gave information about the extent of accumulation of oxygen on the metal surface. These results could be correlated with catalyst deactivation, which was extensive over the most acidic catalysts at low reaction temperatures. Selectivity for the desired product, lactobionic acid, was a maximum of approximately 83% at 93% conversion. The main side-product was lactulose formed via isomerisation of lactose. Lower selectivity toward lactobionic acid was obtained when the rate of oxidation of lactose was low.

AB - Liquid-phase lactose oxidation was investigated over supported Pd/C and Pd-carbon nanofibre catalysts, which were characterized by several methods. A complex relationship between catalyst activity and catalyst acidity was established, i.e. optimum catalyst acidity resulted in the highest activity in lactose oxidation. In-situ catalyst potential measurements during lactose oxidation gave information about the extent of accumulation of oxygen on the metal surface. These results could be correlated with catalyst deactivation, which was extensive over the most acidic catalysts at low reaction temperatures. Selectivity for the desired product, lactobionic acid, was a maximum of approximately 83% at 93% conversion. The main side-product was lactulose formed via isomerisation of lactose. Lower selectivity toward lactobionic acid was obtained when the rate of oxidation of lactose was low.

KW - Active carbon

KW - Carbon nanofibres

KW - Catalyst potential

KW - Lactose oxidation

KW - Palladium

KW - Surface acidity

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DO - 10.1007/s11164-008-0023-3

M3 - Article

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SN - 0922-6168

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SP - 155

EP - 174

JO - Research on Chemical Intermediates

JF - Research on Chemical Intermediates

IS - 2

ER -

Lactose oxidation over palladium catalysts supported on active carbons and on carbon nanofibres

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