New Mn-TiO2 aerogel catalysts for the low-temperature selective catalytic reduction of NOx

A new series of Mn-based catalysts (Mn-TiO 2 , Ce-Mn-TiO 2 , Mn-TiO 2 -SO 4 2 – , and Ce-Mn-TiO 2 -SO 4 2– ) were successfully elaborated using the sol–gel method associated with supercritical drying approach for the low-temperature NO-SCR by NH 3 . The physicochemical properties of aerogel powders...

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Published in:Journal of sol-gel science and technology 2021-02, Vol.97 (2), p.302-310
Main Authors: Arfaoui, Jihene, Ghorbel, Abdelhamid, Petitto, Carolina, Delahay, Gerard
Format: Article
Language:English
Subjects:
Aerogels
Ammonia
Anatase
Catalysis
Catalysts
Ceramics
Chemical reduction
Chemical Sciences
Chemistry and Materials Science
Composites
Conversion
cryogels
etc.
Glass
Inorganic Chemistry
Low temperature
Materials Science
Nanotechnology
Natural Materials
Nitrous oxide
Optical and Electronic Materials
Original Paper: Nano- and macroporous materials (aerogels
Oxidation
Porosity
Properties (attributes)
Selective catalytic reduction
Sol-gel processes
Surface layers
Titanium dioxide
Valence
xerogels
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description A new series of Mn-based catalysts (Mn-TiO 2 , Ce-Mn-TiO 2 , Mn-TiO 2 -SO 4 2 – , and Ce-Mn-TiO 2 -SO 4 2– ) were successfully elaborated using the sol–gel method associated with supercritical drying approach for the low-temperature NO-SCR by NH 3 . The physicochemical properties of aerogel powders were examined by XRD, N 2 -Physisorption at 77 K, NH 3 -TPD, H 2 -TPR, and DRUV-Vis spectroscopy. It was shown that all the catalysts develop essentially the diffraction peaks of TiO 2 anatase phase and are characterized by a nanometer size (ranging between ~5 and 9 nm), developed mesoporous texture, high surface area (S BET  > 104 m 2 /g) and large porosity (V PT  > 0.24 cm 3 /g). The incorporation of Ce and/or SO 4 2– influences differently the structural, textural, acidic, and redox properties of Mn-derived sol–gel catalysts and consequently affects their SCR activity. High NO conversions (>75%) into essentially N 2 O are obtained at low temperatures (150–270 °C) over Mn-TiO 2 and Ce-Mn-TiO 2 aerogel systems. The addition of sulfate modifies the nature of Mn species and noticeably reduces the low-temperature reactivity of catalysts ( T   300 °C) leading to highly active and N 2 -selective Mn-TiO 2 -SO 4 2– and Ce-Mn-TiO 2 -SO 4 2– sulfated catalysts. Above 90% NO conversion into N 2 (100%) was reached, in the NO-SCR by NH 3 , over the new Ce-Mn-TiO 2 -SO 4 2– aerogel catalyst, in the 450–500 °C temperature range. Highlights New Mn-TiO 2 , Ce-Mn-TiO 2 , Mn-TiO 2 −SO 4 2− and Ce-Mn-TiO 2 -SO 4 2− SCR aerogel catalysts. Mn-TiO 2 and Ce-Mn-TiO 2 exhibit high NO conversion into N 2 O between 150 and 270 °C. Ce slightly modifies the physicochemical properties of Mn based catalysts. SO 4 2− affects nature, oxidation state, dispersion of Mn species and NO-SCR activity. Mn-TiO 2 −SO 4 2− and Ce-Mn-TiO 2 −SO 4 2− exhibit high NO conversion into N 2 at T > 300 °C.
doi_str_mv 10.1007/s10971-020-05451-4
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The physicochemical properties of aerogel powders were examined by XRD, N 2 -Physisorption at 77 K, NH 3 -TPD, H 2 -TPR, and DRUV-Vis spectroscopy. It was shown that all the catalysts develop essentially the diffraction peaks of TiO 2 anatase phase and are characterized by a nanometer size (ranging between ~5 and 9 nm), developed mesoporous texture, high surface area (S BET  &gt; 104 m 2 /g) and large porosity (V PT  &gt; 0.24 cm 3 /g). The incorporation of Ce and/or SO 4 2– influences differently the structural, textural, acidic, and redox properties of Mn-derived sol–gel catalysts and consequently affects their SCR activity. High NO conversions (&gt;75%) into essentially N 2 O are obtained at low temperatures (150–270 °C) over Mn-TiO 2 and Ce-Mn-TiO 2 aerogel systems. The addition of sulfate modifies the nature of Mn species and noticeably reduces the low-temperature reactivity of catalysts ( T  &lt; 300 °C). However, it induces, thanks to the contribution of many strong acid sites, a substantial increase of the NO conversion into N 2 at higher temperatures ( T  &gt; 300 °C) leading to highly active and N 2 -selective Mn-TiO 2 -SO 4 2– and Ce-Mn-TiO 2 -SO 4 2– sulfated catalysts. Above 90% NO conversion into N 2 (100%) was reached, in the NO-SCR by NH 3 , over the new Ce-Mn-TiO 2 -SO 4 2– aerogel catalyst, in the 450–500 °C temperature range. Highlights New Mn-TiO 2 , Ce-Mn-TiO 2 , Mn-TiO 2 −SO 4 2− and Ce-Mn-TiO 2 -SO 4 2− SCR aerogel catalysts. Mn-TiO 2 and Ce-Mn-TiO 2 exhibit high NO conversion into N 2 O between 150 and 270 °C. Ce slightly modifies the physicochemical properties of Mn based catalysts. SO 4 2− affects nature, oxidation state, dispersion of Mn species and NO-SCR activity. 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The physicochemical properties of aerogel powders were examined by XRD, N 2 -Physisorption at 77 K, NH 3 -TPD, H 2 -TPR, and DRUV-Vis spectroscopy. It was shown that all the catalysts develop essentially the diffraction peaks of TiO 2 anatase phase and are characterized by a nanometer size (ranging between ~5 and 9 nm), developed mesoporous texture, high surface area (S BET  &gt; 104 m 2 /g) and large porosity (V PT  &gt; 0.24 cm 3 /g). The incorporation of Ce and/or SO 4 2– influences differently the structural, textural, acidic, and redox properties of Mn-derived sol–gel catalysts and consequently affects their SCR activity. High NO conversions (&gt;75%) into essentially N 2 O are obtained at low temperatures (150–270 °C) over Mn-TiO 2 and Ce-Mn-TiO 2 aerogel systems. The addition of sulfate modifies the nature of Mn species and noticeably reduces the low-temperature reactivity of catalysts ( T  &lt; 300 °C). However, it induces, thanks to the contribution of many strong acid sites, a substantial increase of the NO conversion into N 2 at higher temperatures ( T  &gt; 300 °C) leading to highly active and N 2 -selective Mn-TiO 2 -SO 4 2– and Ce-Mn-TiO 2 -SO 4 2– sulfated catalysts. Above 90% NO conversion into N 2 (100%) was reached, in the NO-SCR by NH 3 , over the new Ce-Mn-TiO 2 -SO 4 2– aerogel catalyst, in the 450–500 °C temperature range. Highlights New Mn-TiO 2 , Ce-Mn-TiO 2 , Mn-TiO 2 −SO 4 2− and Ce-Mn-TiO 2 -SO 4 2− SCR aerogel catalysts. Mn-TiO 2 and Ce-Mn-TiO 2 exhibit high NO conversion into N 2 O between 150 and 270 °C. Ce slightly modifies the physicochemical properties of Mn based catalysts. SO 4 2− affects nature, oxidation state, dispersion of Mn species and NO-SCR activity. Mn-TiO 2 −SO 4 2− and Ce-Mn-TiO 2 −SO 4 2− exhibit high NO conversion into N 2 at T &gt; 300 °C.</description><subject>Aerogels</subject><subject>Ammonia</subject><subject>Anatase</subject><subject>Catalysis</subject><subject>Catalysts</subject><subject>Ceramics</subject><subject>Chemical reduction</subject><subject>Chemical Sciences</subject><subject>Chemistry and Materials Science</subject><subject>Composites</subject><subject>Conversion</subject><subject>cryogels</subject><subject>etc.</subject><subject>Glass</subject><subject>Inorganic Chemistry</subject><subject>Low temperature</subject><subject>Materials Science</subject><subject>Nanotechnology</subject><subject>Natural Materials</subject><subject>Nitrous oxide</subject><subject>Optical and Electronic Materials</subject><subject>Original Paper: Nano- and macroporous materials (aerogels</subject><subject>Oxidation</subject><subject>Porosity</subject><subject>Properties (attributes)</subject><subject>Selective catalytic reduction</subject><subject>Sol-gel processes</subject><subject>Surface layers</subject><subject>Titanium dioxide</subject><subject>Valence</subject><subject>xerogels</subject><issn>0928-0707</issn><issn>1573-4846</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2021</creationdate><recordtype>article</recordtype><recordid>eNp9kMFKAzEURYMoWKs_4CrgykX0ZZJJpssiaoVqN3XjJqTTlzoybWqSWvv3po7oztWDy7mXxyHknMMVB9DXkcNAcwYFMChlyZk8ID1easFkJdUh6cGgqBho0MfkJMY3gIxx3SMvT7iljys2bSYFtRj8Alta22TbXUyROh9oekXa-i1LuFxjsGkTkEZssU7NB_6wqalpwPkmZ35FvaNPk89TcuRsG_Hs5_bJ893t9GbExpP7h5vhmNVSyMQslAO0SjhbqpnmXAp02mleVLICVTkpCmG1ck4BiLm0JZ9JC9VsXmNdSudEn1x2u6-2NevQLG3YGW8bMxqOzT4DwYUoFf_gmb3o2HXw7xuMybz5TVjl90whK6UKDhVkquioOvgYA7rfWQ5m79t0vk32bb59G5lLoivFDK8WGP6m_2l9AU1agcc</recordid><startdate>20210201</startdate><enddate>20210201</enddate><creator>Arfaoui, Jihene</creator><creator>Ghorbel, Abdelhamid</creator><creator>Petitto, Carolina</creator><creator>Delahay, Gerard</creator><general>Springer US</general><general>Springer Nature B.V</general><general>Springer Verlag</general><scope>AAYXX</scope><scope>CITATION</scope><scope>8FE</scope><scope>8FG</scope><scope>ABJCF</scope><scope>AFKRA</scope><scope>BENPR</scope><scope>BGLVJ</scope><scope>CCPQU</scope><scope>D1I</scope><scope>DWQXO</scope><scope>HCIFZ</scope><scope>KB.</scope><scope>L6V</scope><scope>M7S</scope><scope>PDBOC</scope><scope>PQEST</scope><scope>PQQKQ</scope><scope>PQUKI</scope><scope>PTHSS</scope><scope>1XC</scope><scope>VOOES</scope><orcidid>https://orcid.org/0000-0002-7146-5281</orcidid></search><sort><creationdate>20210201</creationdate><title>New Mn-TiO2 aerogel catalysts for the low-temperature selective catalytic reduction of NOx</title><author>Arfaoui, Jihene ; 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The physicochemical properties of aerogel powders were examined by XRD, N 2 -Physisorption at 77 K, NH 3 -TPD, H 2 -TPR, and DRUV-Vis spectroscopy. It was shown that all the catalysts develop essentially the diffraction peaks of TiO 2 anatase phase and are characterized by a nanometer size (ranging between ~5 and 9 nm), developed mesoporous texture, high surface area (S BET  &gt; 104 m 2 /g) and large porosity (V PT  &gt; 0.24 cm 3 /g). The incorporation of Ce and/or SO 4 2– influences differently the structural, textural, acidic, and redox properties of Mn-derived sol–gel catalysts and consequently affects their SCR activity. High NO conversions (&gt;75%) into essentially N 2 O are obtained at low temperatures (150–270 °C) over Mn-TiO 2 and Ce-Mn-TiO 2 aerogel systems. The addition of sulfate modifies the nature of Mn species and noticeably reduces the low-temperature reactivity of catalysts ( T  &lt; 300 °C). However, it induces, thanks to the contribution of many strong acid sites, a substantial increase of the NO conversion into N 2 at higher temperatures ( T  &gt; 300 °C) leading to highly active and N 2 -selective Mn-TiO 2 -SO 4 2– and Ce-Mn-TiO 2 -SO 4 2– sulfated catalysts. Above 90% NO conversion into N 2 (100%) was reached, in the NO-SCR by NH 3 , over the new Ce-Mn-TiO 2 -SO 4 2– aerogel catalyst, in the 450–500 °C temperature range. Highlights New Mn-TiO 2 , Ce-Mn-TiO 2 , Mn-TiO 2 −SO 4 2− and Ce-Mn-TiO 2 -SO 4 2− SCR aerogel catalysts. Mn-TiO 2 and Ce-Mn-TiO 2 exhibit high NO conversion into N 2 O between 150 and 270 °C. Ce slightly modifies the physicochemical properties of Mn based catalysts. SO 4 2− affects nature, oxidation state, dispersion of Mn species and NO-SCR activity. Mn-TiO 2 −SO 4 2− and Ce-Mn-TiO 2 −SO 4 2− exhibit high NO conversion into N 2 at T &gt; 300 °C.</abstract><cop>New York</cop><pub>Springer US</pub><doi>10.1007/s10971-020-05451-4</doi><tpages>9</tpages><orcidid>https://orcid.org/0000-0002-7146-5281</orcidid><oa>free_for_read</oa></addata></record>
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subjects Aerogels
Ammonia
Anatase
Catalysis
Catalysts
Ceramics
Chemical reduction
Chemical Sciences
Chemistry and Materials Science
Composites
Conversion
cryogels
etc.
Glass
Inorganic Chemistry
Low temperature
Materials Science
Nanotechnology
Natural Materials
Nitrous oxide
Optical and Electronic Materials
Original Paper: Nano- and macroporous materials (aerogels
Oxidation
Porosity
Properties (attributes)
Selective catalytic reduction
Sol-gel processes
Surface layers
Titanium dioxide
Valence
xerogels
title New Mn-TiO2 aerogel catalysts for the low-temperature selective catalytic reduction of NOx
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