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Mesoporous ferrierite zeolite (FER) synthesized by a post-desilication method was applied for a gas-phase dimethyl ether (DME) carbonylation to confirm the contributions of the newly formed mesoporous structures above 10 nm in size. The distribution o...
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RISS 인기검색어
Contributions of post-synthesized mesopore structures of ferrierite zeolite for gas-phase dimethyl ether carbonylation activity
한글로보기부가정보
다국어 초록 (Multilingual Abstract)
Mesoporous ferrierite zeolite (FER) synthesized by a post-desilication method was applied for a gas-phase dimethyl ether (DME) carbonylation to confirm the contributions of the newly formed mesoporous structures above 10 nm in size. The distribution of surface acidic sites and extent of coke deposition was significantly altered, resulting in showing different catalytic activity and stability, which were mainly caused by the post-synthesized larger mesopores on the FER. The newly formed mesoporous structures in the range of 5-40 nm on the pristine seed-derived FER (SFER) with a Si/Al molar ratio of 10.4 were largely changed by a desilication/recrystallization duration, and the mesopores significantly increased the surface acidic sites with similar extent of crystallinity even with a lower Si/Al ratio of 6.7-8.6.
The increased strong acidic sites corresponding to Brønsted acid sites after an optimal desilication duration for ~3 h on the mesoporous SFER (m-SFER(3)) were mainly responsible for an increased DME carbonylation activity with smaller formation of coke precursors due to facile mass transport phenomena through its lager mesopores.
The increased strong acidic sites corresponding to Brønsted acid sites after an optimal desilication duration for ~3 h on the mesoporous SFER (m-SFER(3)) were mainly responsible for an increased DME carbonylation activity with smaller formation of coke precursors due to facile mass transport phenomena through its lager mesopores.
Mesoporous ferrierite zeolite (FER) synthesized by a post-desilication method was applied for a gas-phase dimethyl ether (DME) carbonylation to confirm the contributions of the newly formed mesoporous structures above 10 nm in size. The distribution of surface acidic sites and extent of coke deposition was significantly altered, resulting in showing different catalytic activity and stability, which were mainly caused by the post-synthesized larger mesopores on the FER. The newly formed mesoporous structures in the range of 5-40 nm on the pristine seed-derived FER (SFER) with a Si/Al molar ratio of 10.4 were largely changed by a desilication/recrystallization duration, and the mesopores significantly increased the surface acidic sites with similar extent of crystallinity even with a lower Si/Al ratio of 6.7-8.6.
The increased strong acidic sites corresponding to Brønsted acid sites after an optimal desilication duration for ~3 h on the mesoporous SFER (m-SFER(3)) were mainly responsible for an increased DME carbonylation activity with smaller formation of coke precursors due to facile mass transport phenomena through its lager mesopores.
참고문헌 (Reference)
1 H. Zhang, 21 : 9494-, 2011
2 M. V. Morales, 562 : 215-, 2018
3 H. S. Jung, 339 : 79-, 2020
4 S. Y. Park, 75 : 28-, 2016
5 H. Ham, 10 (10): 5135-, 2020
6 P. Sarv, 102 : 1372-, 1998
7 J. H. Kim, 8 : 3060-, 2018
8 B. Li, 117 : 5840-, 2013
9 A. Bhan, 129 : 4919-, 2007
10 P. Cheung, 45 : 1617-, 2006
1 H. Zhang, 21 : 9494-, 2011
2 M. V. Morales, 562 : 215-, 2018
3 H. S. Jung, 339 : 79-, 2020
4 S. Y. Park, 75 : 28-, 2016
5 H. Ham, 10 (10): 5135-, 2020
6 P. Sarv, 102 : 1372-, 1998
7 J. H. Kim, 8 : 3060-, 2018
8 B. Li, 117 : 5840-, 2013
9 A. Bhan, 129 : 4919-, 2007
10 P. Cheung, 45 : 1617-, 2006
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12 X. Cheng, 260 : 132-, 2018
13 J. C. Groen, 23 : 101-, 2006
14 S. Kasipandi, 31 : 1803390-, 2019
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17 K. Li, 6 : 46-, 2014
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21 J. C. Groen, 251 : 21-, 2007
22 K. P. de Jong, 49 : 10074-, 2011
23 A. Bonilla, 265 : 170-, 2009
24 K. Möller, 42 : 3689-, 2013
25 D. Verboekend, 115 : 14193-, 2011
26 X. W. Cheng, 1 : 136-, 2013
27 Yu. P. Khitev, 146 : 201-, 2011
28 Yu. P. Khitev, 441-442 : 124-, 2012
29 I. I. Ivanova, 42 : 3671-, 2013
30 R. Chal, 46 : 7840-, 2010
31 R. Chal, 3 : 67-, 2011
32 J. Garcia-Martinez, 2 : 987-, 2012
33 M. Manko, 170 : 243-, 2013
34 C. Bertrand-Drira, 213 : 142-, 2015
35 Y. Han, 7 : 326-, 2011
36 T. Gott, 263 : 359-, 2009
37 D. B. Rasmussen, 54 : 1-, 2015
38 J. A. Z. Pieterse, 187 : 518-, 1999
39 K. Saravanan, 3 : 808-, 2018
40 K. Saravanan, 172-173 : 108-, 2015
41 H. Li, 200 : 182-, 2017
42 A. Auroux, 19 (19): 205-, 2002
43 H. S. Jung, 310 : 110669-, 2021
44 A. A. C. Reule, 6 : 4972-, 2016
45 J. Xu, 30 : 1076-, 2009
46 F. Goodarzia, 292 : 109730-, 2020
47 Xue Li, "Synthesis of Co-doped micro-mesoporous SAPO-11 zeolite for glycerol hydrogenolysis" 한국화학공학회 37 (37): 216-223, 2020
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분석정보
인용정보 인용지수 설명보기
학술지 이력
| 연월일 | 이력구분 | 이력상세 | 등재구분 |
|---|---|---|---|
| 2023 | 평가예정 | 해외DB학술지평가 신청대상 (해외등재 학술지 평가) | |
| 2020-01-01 | 평가 | 등재학술지 유지 (해외등재 학술지 평가) | |
| 2016-06-21 | 학술지명변경 | 한글명 : The Korean Journal of Chemical Engineering -> Korean Journal of Chemical Engineering외국어명 : The Korean Journal of Chemical Engineering -> Korean Journal of Chemical Engineering | |
| 2011-01-01 | 평가 | 등재학술지 유지 (등재유지) | |
| 2009-01-01 | 평가 | 등재학술지 유지 (등재유지) | |
| 2007-09-27 | 학회명변경 | 영문명 : The Korean Institute Of Chemical Engineers -> The Korean Institute of Chemical Engineers | |
| 2007-09-03 | 학술지명변경 | 한글명 : The Korean Journal of Chemical Engineeri -> The Korean Journal of Chemical Engineering외국어명 : The Korean Journal of Chemical Engineeri -> The Korean Journal of Chemical Engineering | |
| 2007-01-01 | 평가 | 등재학술지 유지 (등재유지) | |
| 2005-01-01 | 평가 | 등재학술지 유지 (등재유지) | |
| 2002-01-01 | 평가 | 등재학술지 선정 (등재후보2차) | |
| 1999-07-01 | 평가 | 등재후보학술지 선정 (신규평가) |  |
학술지 인용정보
| 기준연도 | WOS-KCI 통합IF(2년) | KCIF(2년) | KCIF(3년) |
|---|---|---|---|
| 2016 | 1.92 | 0.72 | 1.4 |
| KCIF(4년) | KCIF(5년) | 중심성지수(3년) | 즉시성지수 |
| 1.15 | 0.94 | 0.403 | 0.14 |
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