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Superior low temperature activity over α-MnO 2 /β-MnOOH catalyst for selective catalytic reduction of NO x with ammonia
Manganese octahedral molecular sieves with an α-MnO crystal structure (OMS-2) and their related materials have attracted significant attention for the selective catalytic reduction of NO using NH (NH -SCR) at low temperatures. Further lowering their operating temperature should be an effective metho...
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| Published in: | RSC advances 2024-11, Vol.14 (48), p.35498-35504 |
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| Main Authors: | , , , , , , , |
| Format: | Article |
| Language: | English |
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| cites | cdi_FETCH-LOGICAL-c585-7bc15ab6feb8afb802c208bb60b93b574de7ca1fd63964b9f4188cd6353c60fc3 |
| container_end_page | 35504 |
| container_issue | 48 |
| container_start_page | 35498 |
| container_title | RSC advances |
| container_volume | 14 |
| creator | Takemoto, Masanori Fujinuma, Haruko Sugawara, Yoshihiro Sasaki, Yukichi Iyoki, Kenta Okubo, Tatsuya Yamaguchi, Kazuya Wakihara, Toru |
| description | Manganese octahedral molecular sieves with an α-MnO
crystal structure (OMS-2) and their related materials have attracted significant attention for the selective catalytic reduction of NO
using NH
(NH
-SCR) at low temperatures. Further lowering their operating temperature should be an effective method to develop an environmentally friendly de-NO
system; however, their catalytic activity at low temperatures, especially below 100 °C, remains poor. This study describes a post-synthetic approach to develop Mn-based catalysts superior to those in the literature that operate at ultralow temperatures. Post-synthetic planetary ball milling for OMS-2 caused the partial conversion of OMS-2 into β-MnOOH. The obtained nanocomposite catalysts possessed abundant surface oxygen vacancies and strong surface acidity, allowing the milled catalyst to exhibit higher NO conversion at 90 °C (91%) than that in freshly prepared OMS-2 without planetary ball milling (29%). Lowering the operation temperature of OMS-2 catalysts contributed to the suppression of N
O evolution during NH
-SCR over manganese-based catalysts, resulting in high N
selectivity over the milled OMS-2 catalyst (93%). |
| doi_str_mv | 10.1039/D4RA05934D |
| format | article |
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crystal structure (OMS-2) and their related materials have attracted significant attention for the selective catalytic reduction of NO
using NH
(NH
-SCR) at low temperatures. Further lowering their operating temperature should be an effective method to develop an environmentally friendly de-NO
system; however, their catalytic activity at low temperatures, especially below 100 °C, remains poor. This study describes a post-synthetic approach to develop Mn-based catalysts superior to those in the literature that operate at ultralow temperatures. Post-synthetic planetary ball milling for OMS-2 caused the partial conversion of OMS-2 into β-MnOOH. The obtained nanocomposite catalysts possessed abundant surface oxygen vacancies and strong surface acidity, allowing the milled catalyst to exhibit higher NO conversion at 90 °C (91%) than that in freshly prepared OMS-2 without planetary ball milling (29%). Lowering the operation temperature of OMS-2 catalysts contributed to the suppression of N
O evolution during NH
-SCR over manganese-based catalysts, resulting in high N
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crystal structure (OMS-2) and their related materials have attracted significant attention for the selective catalytic reduction of NO
using NH
(NH
-SCR) at low temperatures. Further lowering their operating temperature should be an effective method to develop an environmentally friendly de-NO
system; however, their catalytic activity at low temperatures, especially below 100 °C, remains poor. This study describes a post-synthetic approach to develop Mn-based catalysts superior to those in the literature that operate at ultralow temperatures. Post-synthetic planetary ball milling for OMS-2 caused the partial conversion of OMS-2 into β-MnOOH. The obtained nanocomposite catalysts possessed abundant surface oxygen vacancies and strong surface acidity, allowing the milled catalyst to exhibit higher NO conversion at 90 °C (91%) than that in freshly prepared OMS-2 without planetary ball milling (29%). Lowering the operation temperature of OMS-2 catalysts contributed to the suppression of N
O evolution during NH
-SCR over manganese-based catalysts, resulting in high N
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crystal structure (OMS-2) and their related materials have attracted significant attention for the selective catalytic reduction of NO
using NH
(NH
-SCR) at low temperatures. Further lowering their operating temperature should be an effective method to develop an environmentally friendly de-NO
system; however, their catalytic activity at low temperatures, especially below 100 °C, remains poor. This study describes a post-synthetic approach to develop Mn-based catalysts superior to those in the literature that operate at ultralow temperatures. Post-synthetic planetary ball milling for OMS-2 caused the partial conversion of OMS-2 into β-MnOOH. The obtained nanocomposite catalysts possessed abundant surface oxygen vacancies and strong surface acidity, allowing the milled catalyst to exhibit higher NO conversion at 90 °C (91%) than that in freshly prepared OMS-2 without planetary ball milling (29%). Lowering the operation temperature of OMS-2 catalysts contributed to the suppression of N
O evolution during NH
-SCR over manganese-based catalysts, resulting in high N
selectivity over the milled OMS-2 catalyst (93%).</abstract><cop>England</cop><pmid>39507685</pmid><doi>10.1039/D4RA05934D</doi><tpages>7</tpages><orcidid>https://orcid.org/0000-0002-3916-3849</orcidid><orcidid>https://orcid.org/0000-0002-1111-7111</orcidid><orcidid>https://orcid.org/0000-0002-3043-5676</orcidid><orcidid>https://orcid.org/0000-0002-1681-0193</orcidid><orcidid>https://orcid.org/0000-0002-7661-4936</orcidid></addata></record> |
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| title | Superior low temperature activity over α-MnO 2 /β-MnOOH catalyst for selective catalytic reduction of NO x with ammonia |
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