Kinetic modeling of nitrate reduction catalyzed by Pd-Cu supported on carbon nanotubes

Olívia Salomé G.P. Soares; Xiaolei Fan; José J.M. Órfão; Alexei A. Lapkin; Manuel Fernando R. Pereira

doi:10.1021/ie202957v

Kinetic modeling of nitrate reduction catalyzed by Pd-Cu supported on carbon nanotubes

Olívia Salomé G.P. Soares, Xiaolei Fan, José J.M. Órfão, Alexei A. Lapkin, Manuel Fernando R. Pereira

Research output: Journal Publication › Article › peer-review

17 Citations (Scopus)

Abstract

New catalysts for liquid phase nitrate reduction were recently synthesized using multiwalled carbon nanotubes as a support. The most promising catalyst (1%Pd-1%Cu/CNT) was used in this kinetic study. The catalyst experimentally showed high selectivity to nitrogen, between 80 and 89%. A mechanistic model was applied to experimental data to show that the reason for high selectivity is due to the enhanced mass transfer near the catalyst surface promoted by the use of a structured support. The experimental selectivity is close to the maximum selectivity predicted for this catalytic system at the best operating conditions and in the absence of any mass transfer limitations.

Original language	English
Pages (from-to)	4854-4860
Number of pages	7
Journal	Industrial and Engineering Chemistry Research
Volume	51
Issue number	13
DOIs	https://doi.org/10.1021/ie202957v
Publication status	Published - 4 Apr 2012
Externally published	Yes

ASJC Scopus subject areas

General Chemistry
General Chemical Engineering
Industrial and Manufacturing Engineering

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10.1021/ie202957v

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title = "Kinetic modeling of nitrate reduction catalyzed by Pd-Cu supported on carbon nanotubes",

abstract = "New catalysts for liquid phase nitrate reduction were recently synthesized using multiwalled carbon nanotubes as a support. The most promising catalyst (1%Pd-1%Cu/CNT) was used in this kinetic study. The catalyst experimentally showed high selectivity to nitrogen, between 80 and 89%. A mechanistic model was applied to experimental data to show that the reason for high selectivity is due to the enhanced mass transfer near the catalyst surface promoted by the use of a structured support. The experimental selectivity is close to the maximum selectivity predicted for this catalytic system at the best operating conditions and in the absence of any mass transfer limitations.",

author = "Soares, {Ol{\'i}via Salom{\'e} G.P.} and Xiaolei Fan and {\'O}rf{\~a}o, {Jos{\'e} J.M.} and Lapkin, {Alexei A.} and Pereira, {Manuel Fernando R.}",

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AU - Soares, Olívia Salomé G.P.

AU - Fan, Xiaolei

AU - Órfão, José J.M.

AU - Lapkin, Alexei A.

AU - Pereira, Manuel Fernando R.

PY - 2012/4/4

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N2 - New catalysts for liquid phase nitrate reduction were recently synthesized using multiwalled carbon nanotubes as a support. The most promising catalyst (1%Pd-1%Cu/CNT) was used in this kinetic study. The catalyst experimentally showed high selectivity to nitrogen, between 80 and 89%. A mechanistic model was applied to experimental data to show that the reason for high selectivity is due to the enhanced mass transfer near the catalyst surface promoted by the use of a structured support. The experimental selectivity is close to the maximum selectivity predicted for this catalytic system at the best operating conditions and in the absence of any mass transfer limitations.

AB - New catalysts for liquid phase nitrate reduction were recently synthesized using multiwalled carbon nanotubes as a support. The most promising catalyst (1%Pd-1%Cu/CNT) was used in this kinetic study. The catalyst experimentally showed high selectivity to nitrogen, between 80 and 89%. A mechanistic model was applied to experimental data to show that the reason for high selectivity is due to the enhanced mass transfer near the catalyst surface promoted by the use of a structured support. The experimental selectivity is close to the maximum selectivity predicted for this catalytic system at the best operating conditions and in the absence of any mass transfer limitations.

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JO - Industrial and Engineering Chemistry Research

JF - Industrial and Engineering Chemistry Research

IS - 13

ER -

Kinetic modeling of nitrate reduction catalyzed by Pd-Cu supported on carbon nanotubes

Abstract

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