Superlattice-based plasmonic catalysis: concentrating light at the nanoscale to drive efficient nitrogen-to-ammonia fixation at ambient conditions
Plasmonic catalysis promises green ammonia synthesis but is limited by the need for co-catalysts and poor performances due to weak electromagnetic field enhancement. Here, we use two-dimensional plasmonic superlattices with dense electromagnetic hotspots to boost ambient nitrogen-to-ammonia photocon...
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sg-ntu-dr.10356-1688732023-06-23T15:32:00Z Superlattice-based plasmonic catalysis: concentrating light at the nanoscale to drive efficient nitrogen-to-ammonia fixation at ambient conditions Boong, Siew Kheng Chong, Carice Lee, Jinn-Kye Ang, Zhi Zhong Li, Haitao Lee, Hiang Kwee School of Chemistry, Chemical Engineering and Biotechnology Institute of Materials Research and Engineering, A*STAR Science::Chemistry Ammonia Generation Plasmonic Catalysis Plasmonic catalysis promises green ammonia synthesis but is limited by the need for co-catalysts and poor performances due to weak electromagnetic field enhancement. Here, we use two-dimensional plasmonic superlattices with dense electromagnetic hotspots to boost ambient nitrogen-to-ammonia photoconversion without needing co-catalyst. By organizing Ag octahedra into a square superlattice to concentrate light, the ammonia formation is enhanced by ≈15-fold and 4-fold over hexagonal superlattice and disorganized array, respectively. Our unique catalyst achieves superior ammonia formation rate and apparent quantum yield up to ≈15-fold and ≈103 -fold, respectively, better than traditional designs. Mechanistic investigations reveal the abundance of intense plasmonic hotspots is crucial to promote hot electron generation and transfer for nitrogen reduction. Our work offers valuable insights to design electromagnetically hot plasmonic catalysts for diverse chemical and energy applications. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) Nanyang Technological University H.K.L. thanks the funding supports from Singapore Ministry of Education (RS13/20 and RG4/21), Agency for Science, Technology and Research, Singapore (A*STAR, A2084c0158), Center of Hydrogen Innovation, National University of Singapore (CHI-P2022-05), and Nanyang Technological University start-up grants. The research was conducted as a part of NICES (NTU-IMRE Chemistry Lab for Eco Sustainability; REQ0275931), a joint research initiative between Nanyang Technological University (NTU) and Institute of Materials Research and Engineering (IMRE) from Agency for Science, Technology and Research(A*STAR). 2023-06-21T01:11:41Z 2023-06-21T01:11:41Z 2023 Journal Article Boong, S. K., Chong, C., Lee, J., Ang, Z. Z., Li, H. & Lee, H. K. (2023). Superlattice-based plasmonic catalysis: concentrating light at the nanoscale to drive efficient nitrogen-to-ammonia fixation at ambient conditions. Angewandte Chemie (International Ed. in English), 62(7), e202216562-. https://dx.doi.org/10.1002/anie.202216562 1433-7851 https://hdl.handle.net/10356/168873 10.1002/anie.202216562 36504182 2-s2.0-85146042097 7 62 e202216562 en RS13/20 RG4/21 A2084c0158 CHI-P2022–05 NTU-SUG REQ0275931 Angewandte Chemie (International ed. in English) © 2022 Wiley-VCH GmbH. All rights reserved. application/pdf |
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Science::Chemistry Ammonia Generation Plasmonic Catalysis Boong, Siew Kheng Chong, Carice Lee, Jinn-Kye Ang, Zhi Zhong Li, Haitao Lee, Hiang Kwee Superlattice-based plasmonic catalysis: concentrating light at the nanoscale to drive efficient nitrogen-to-ammonia fixation at ambient conditions |
| description |
Plasmonic catalysis promises green ammonia synthesis but is limited by the need for co-catalysts and poor performances due to weak electromagnetic field enhancement. Here, we use two-dimensional plasmonic superlattices with dense electromagnetic hotspots to boost ambient nitrogen-to-ammonia photoconversion without needing co-catalyst. By organizing Ag octahedra into a square superlattice to concentrate light, the ammonia formation is enhanced by ≈15-fold and 4-fold over hexagonal superlattice and disorganized array, respectively. Our unique catalyst achieves superior ammonia formation rate and apparent quantum yield up to ≈15-fold and ≈103 -fold, respectively, better than traditional designs. Mechanistic investigations reveal the abundance of intense plasmonic hotspots is crucial to promote hot electron generation and transfer for nitrogen reduction. Our work offers valuable insights to design electromagnetically hot plasmonic catalysts for diverse chemical and energy applications. |
| author2 |
School of Chemistry, Chemical Engineering and Biotechnology |
| author_facet |
School of Chemistry, Chemical Engineering and Biotechnology Boong, Siew Kheng Chong, Carice Lee, Jinn-Kye Ang, Zhi Zhong Li, Haitao Lee, Hiang Kwee |
| format |
Article |
| author |
Boong, Siew Kheng Chong, Carice Lee, Jinn-Kye Ang, Zhi Zhong Li, Haitao Lee, Hiang Kwee |
| author_sort |
Boong, Siew Kheng |
| title |
Superlattice-based plasmonic catalysis: concentrating light at the nanoscale to drive efficient nitrogen-to-ammonia fixation at ambient conditions |
| title_short |
Superlattice-based plasmonic catalysis: concentrating light at the nanoscale to drive efficient nitrogen-to-ammonia fixation at ambient conditions |
| title_full |
Superlattice-based plasmonic catalysis: concentrating light at the nanoscale to drive efficient nitrogen-to-ammonia fixation at ambient conditions |
| title_fullStr |
Superlattice-based plasmonic catalysis: concentrating light at the nanoscale to drive efficient nitrogen-to-ammonia fixation at ambient conditions |
| title_full_unstemmed |
Superlattice-based plasmonic catalysis: concentrating light at the nanoscale to drive efficient nitrogen-to-ammonia fixation at ambient conditions |
| title_sort |
superlattice-based plasmonic catalysis: concentrating light at the nanoscale to drive efficient nitrogen-to-ammonia fixation at ambient conditions |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/168873 |
| _version_ |
1772825845590654976 |