Plasma-assisted catalysis for volatile organic compounds abatement

A dielectric barrier discharge (DBD) combined with Mn-based phosphate catalysts placed downstream of the plasma reactor was investigated experimentally for total oxidation of toluene in air. The discharge was initiated by high voltage pulses of 18kV amplitude and 12–13ns rise time. The pulse frequen...

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Published in:Applied catalysis. B, Environmental Vol. 61; no. 1-2; pp. 12 - 20
Main Authors: Magureanu, Monica, Mandache, Nicolae B., Eloy, Pierre, Gaigneaux, Eric M., Parvulescu, Vasile I.
Format: Journal Article
Language:English
Published: Elsevier B.V 27.10.2005
Subjects:
Dielectric barrier discharge
Heterogeneous catalysis
Plasma
Volatile organic compounds
Volatile organic compounds
Plasma
Heterogeneous catalysis
Dielectric barrier discharge
ISSN:0926-3373, 1873-3883
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Abstract A dielectric barrier discharge (DBD) combined with Mn-based phosphate catalysts placed downstream of the plasma reactor was investigated experimentally for total oxidation of toluene in air. The discharge was initiated by high voltage pulses of 18kV amplitude and 12–13ns rise time. The pulse frequency increased from 14 to 80Hz, for applied voltages in the range 18–28kV. Discharge currents up to 100 A and approximately 50ns duration were obtained. No other hydrocarbons except toluene were detected in the effluent gas. The yield of carbon dioxide formed in the discharge was up to 24%. As catalysts, MnPO4, Mn-APO-5 and Mn-SAPO-11 were tested, for temperatures up to 400°C. Under purely catalytic conditions, the best behavior for toluene total oxidation was found for Mn-SAPO-11, with a CO2 yield up to 33%, at 400°C. The combined application of plasma and catalysis showed a remarkable synergetic effect, even at low temperature, up to 100°C, where the catalysts alone are not active. In this range, the CO2 yield increased up to 41%, for the Mn-SAPO catalyst. At 400°C the highest CO2 yield was obtained for MnPO4, reaching 68%. The synergetic effect observed for the plasma–catalyst combination is attributed to ozone radicals formed in the discharge, which decompose on the catalyst surface, greatly contributing to toluene total oxidation.
AbstractList A dielectric barrier discharge (DBD) combined with Mn-based phosphate catalysts placed downstream of the plasma reactor was investigated experimentally for total oxidation of toluene in air. The discharge was initiated by high voltage pulses of 18 kV amplitude and 12-13 ns rise time. The pulse frequency increased from 14 to 80 Hz, for applied voltages in the range 18-28 kV. Discharge currents up to 100 A and approximately 50 ns duration were obtained. No other hydrocarbons except toluene were detected in the effluent gas. The yield of carbon dioxide formed in the discharge was up to 24%. As catalysts, MnPO sub(4), Mn-APO-5 and Mn-SAPO-11 were tested, for temperatures up to 400 degree C. Under purely catalytic conditions, the best behavior for toluene total oxidation was found for Mn-SAPO-11, with a CO sub(2) yield up to 33%, at 400 degree C. The combined application of plasma and catalysis showed a remarkable synergetic effect, even at low temperature, up to 100 degree C, where the catalysts alone are not active. In this range, the CO sub(2) yield increased up to 41%, for the Mn-SAPO catalyst. At 400 degree C the highest CO sub(2) yield was obtained for MnPO sub(4), reaching 68%. The synergetic effect observed for the plasma-catalyst combination is attributed to ozone radicals formed in the discharge, which decompose on the catalyst surface, greatly contributing to toluene total oxidation.
A dielectric barrier discharge (DBD) combined with Mn-based phosphate catalysts placed downstream of the plasma reactor was investigated experimentally for total oxidation of toluene in air. The discharge was initiated by high voltage pulses of 18kV amplitude and 12-13ns rise time. The pulse frequency increased from 14 to 80Hz, for applied voltages in the range 18-28kV. Discharge currents up to 100 A and approximately 50ns duration were obtained. No other hydrocarbons except toluene were detected in the effluent gas. The yield of carbon dioxide formed in the discharge was up to 24%. As catalysts, MnPO4, Mn-APO-5 and Mn-SAPO-11 were tested, for temperatures up to 400 deg C. Under purely catalytic conditions, the best behavior for toluene total oxidation was found for Mn-SAPO-11, with a CO2 yield up to 33%, at 400 deg C. The combined application of plasma and catalysis showed a remarkable synergetic effect, even at low temperature, up to 100 deg C, where the catalysts alone are not active. In this range, the CO2 yield increased up to 41%, for the Mn-SAPO catalyst. At 400 deg C the highest CO2 yield was obtained for MnPO4, reaching 68%. The synergetic effect observed for the plasma-catalyst combination is attributed to ozone radicals formed in the discharge, which decompose on the catalyst surface, greatly contributing to toluene total oxidation.
A dielectric barrier discharge (DBD) combined with Mn-based phosphate catalysts placed downstream of the plasma reactor was investigated experimentally for total oxidation of toluene in air. The discharge was initiated by high voltage pulses of 18kV amplitude and 12–13ns rise time. The pulse frequency increased from 14 to 80Hz, for applied voltages in the range 18–28kV. Discharge currents up to 100 A and approximately 50ns duration were obtained. No other hydrocarbons except toluene were detected in the effluent gas. The yield of carbon dioxide formed in the discharge was up to 24%. As catalysts, MnPO4, Mn-APO-5 and Mn-SAPO-11 were tested, for temperatures up to 400°C. Under purely catalytic conditions, the best behavior for toluene total oxidation was found for Mn-SAPO-11, with a CO2 yield up to 33%, at 400°C. The combined application of plasma and catalysis showed a remarkable synergetic effect, even at low temperature, up to 100°C, where the catalysts alone are not active. In this range, the CO2 yield increased up to 41%, for the Mn-SAPO catalyst. At 400°C the highest CO2 yield was obtained for MnPO4, reaching 68%. The synergetic effect observed for the plasma–catalyst combination is attributed to ozone radicals formed in the discharge, which decompose on the catalyst surface, greatly contributing to toluene total oxidation.
Author Gaigneaux, Eric M.
Mandache, Nicolae B.
Magureanu, Monica
Eloy, Pierre
Parvulescu, Vasile I.
Author_xml – sequence: 1
  givenname: Monica
  surname: Magureanu
  fullname: Magureanu, Monica
  email: monimag@infim.ro
  organization: National Institute for Lasers, Plasma and Radiation Physics, Plasma Physics and Nuclear Fusion Department, Str. Atomistilor 409, C.P. MG-36, 76900 Bucharest, Romania
– sequence: 2
  givenname: Nicolae B.
  surname: Mandache
  fullname: Mandache, Nicolae B.
  organization: National Institute for Lasers, Plasma and Radiation Physics, Plasma Physics and Nuclear Fusion Department, Str. Atomistilor 409, C.P. MG-36, 76900 Bucharest, Romania
– sequence: 3
  givenname: Pierre
  surname: Eloy
  fullname: Eloy, Pierre
  organization: Catholic University of Louvain, Unité de Catalyse et Chimie des Matériaux Divisés, Croix du Sud 2/17, B-1348 Louvain-la Neuve, Belgium
– sequence: 4
  givenname: Eric M.
  surname: Gaigneaux
  fullname: Gaigneaux, Eric M.
  organization: Catholic University of Louvain, Unité de Catalyse et Chimie des Matériaux Divisés, Croix du Sud 2/17, B-1348 Louvain-la Neuve, Belgium
– sequence: 5
  givenname: Vasile I.
  surname: Parvulescu
  fullname: Parvulescu, Vasile I.
  email: v_parvulescu@chem.unibuc.ro
  organization: University of Bucharest, Department of Chemical Technology and Catalysis, B-dul Regina Elisabeta 4-12, 030016 Bucharest, Romania
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Issue 1-2
Keywords Volatile organic compounds
Plasma
Heterogeneous catalysis
Dielectric barrier discharge
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SubjectTerms Dielectric barrier discharge
Heterogeneous catalysis
Plasma
Volatile organic compounds
Title Plasma-assisted catalysis for volatile organic compounds abatement
URI https://dx.doi.org/10.1016/j.apcatb.2005.04.007
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