Catalyst-on-hotspot nanoarchitecture: plasmonic focusing of light onto co-photocatalyst for efficient light-to-chemical transformation
Plasmon-mediated catalysis utilizing hybrid photocatalytic ensembles promises effective light-to-chemical transformation, but current approaches suffer from weak electromagnetic field enhancements from polycrystalline and isotropic plasmonic nanoparticles as well as poor utilization of precious co-c...
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sg-ntu-dr.10356-1746532024-04-12T15:31:57Z Catalyst-on-hotspot nanoarchitecture: plasmonic focusing of light onto co-photocatalyst for efficient light-to-chemical transformation Chong, Carice Boong, Siew Kheng Raja Mogan, Tharishinny 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 Chemistry Electromagnetic hotspots Light-concentrating effect Plasmon-mediated catalysis utilizing hybrid photocatalytic ensembles promises effective light-to-chemical transformation, but current approaches suffer from weak electromagnetic field enhancements from polycrystalline and isotropic plasmonic nanoparticles as well as poor utilization of precious co-catalyst. Here, efficient plasmon-mediated catalysis is achieved by introducing a unique catalyst-on-hotspot nanoarchitecture obtained through the strategic positioning of co-photocatalyst onto plasmonic hotspots to concentrate light energy directly at the point-of-reaction. Using environmental remediation as a proof-of-concept application, the catalyst-on-hotspot design (edge-AgOcta@Cu2 O) enhances photocatalytic advanced oxidation processes to achieve superior organic-pollutant degradation at ≈81% albeit having lesser Cu2 O co-photocatalyst than the fully deposited design (full-AgOcta@Cu2 O). Mass-normalized rate constants of edge-AgOcta@Cu2 O reveal up to 20-fold and 3-fold more efficient utilization of Cu2 O and Ag nanoparticles, respectively, compared to full-AgOcta@Cu2 O and standalone catalysts. Moreover, this design also exhibits catalytic performance >4-fold better than emerging hybrid photocatalytic platforms. Mechanistic studies unveil that the light-concentrating effect facilitated by the dense electromagnetic hotspots is crucial to promote the generation and utilization of energetic photocarriers for enhanced catalysis. By enabling the plasmonic focusing of light onto co-photocatalyst at the single-particle level, the unprecedented design offers valuable insights in enhancing light-driven chemical reactions and realizing efficient energy/catalyst utilizations for diverse chemical, environmental, and energy applications. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) Nanyang Technological University Submitted/Accepted version H.K.L. thanks the funding supports from the Singapore Ministry of Education (AcRF Tier 1 RS13/20 and RG4/21), A*STAR Singapore (AME YIRG A2084c0158), the National University of Singapore Center of Hydrogen Innovation (CHI-P2022-05), and the 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). 2024-04-07T02:07:54Z 2024-04-07T02:07:54Z 2024 Journal Article Chong, C., Boong, S. K., Raja Mogan, T., Lee, J., Ang, Z. Z., Li, H. & Lee, H. K. (2024). Catalyst-on-hotspot nanoarchitecture: plasmonic focusing of light onto co-photocatalyst for efficient light-to-chemical transformation. Small. https://dx.doi.org/10.1002/smll.202309983 1613-6810 https://hdl.handle.net/10356/174653 10.1002/smll.202309983 38174596 en RS13/20 RG4/21 AME-YIRG-A2084c0158 CHI-P2022-05 NTU-SUG REQ0275931 Small © 2024 Wiley-VCH GmbH. All rights reserved. This article may be downloaded for personal use only. Any other use requires prior permission of the copyright holder. The Version of Record is available online at http://doi.org/10.1002/smll.202309983. application/pdf |
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Chemistry Electromagnetic hotspots Light-concentrating effect |
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Chemistry Electromagnetic hotspots Light-concentrating effect Chong, Carice Boong, Siew Kheng Raja Mogan, Tharishinny Lee, Jinn-Kye Ang, Zhi Zhong Li, Haitao Lee, Hiang Kwee Catalyst-on-hotspot nanoarchitecture: plasmonic focusing of light onto co-photocatalyst for efficient light-to-chemical transformation |
| description |
Plasmon-mediated catalysis utilizing hybrid photocatalytic ensembles promises effective light-to-chemical transformation, but current approaches suffer from weak electromagnetic field enhancements from polycrystalline and isotropic plasmonic nanoparticles as well as poor utilization of precious co-catalyst. Here, efficient plasmon-mediated catalysis is achieved by introducing a unique catalyst-on-hotspot nanoarchitecture obtained through the strategic positioning of co-photocatalyst onto plasmonic hotspots to concentrate light energy directly at the point-of-reaction. Using environmental remediation as a proof-of-concept application, the catalyst-on-hotspot design (edge-AgOcta@Cu2 O) enhances photocatalytic advanced oxidation processes to achieve superior organic-pollutant degradation at ≈81% albeit having lesser Cu2 O co-photocatalyst than the fully deposited design (full-AgOcta@Cu2 O). Mass-normalized rate constants of edge-AgOcta@Cu2 O reveal up to 20-fold and 3-fold more efficient utilization of Cu2 O and Ag nanoparticles, respectively, compared to full-AgOcta@Cu2 O and standalone catalysts. Moreover, this design also exhibits catalytic performance >4-fold better than emerging hybrid photocatalytic platforms. Mechanistic studies unveil that the light-concentrating effect facilitated by the dense electromagnetic hotspots is crucial to promote the generation and utilization of energetic photocarriers for enhanced catalysis. By enabling the plasmonic focusing of light onto co-photocatalyst at the single-particle level, the unprecedented design offers valuable insights in enhancing light-driven chemical reactions and realizing efficient energy/catalyst utilizations for diverse chemical, environmental, and energy applications. |
| author2 |
School of Chemistry, Chemical Engineering and Biotechnology |
| author_facet |
School of Chemistry, Chemical Engineering and Biotechnology Chong, Carice Boong, Siew Kheng Raja Mogan, Tharishinny Lee, Jinn-Kye Ang, Zhi Zhong Li, Haitao Lee, Hiang Kwee |
| format |
Article |
| author |
Chong, Carice Boong, Siew Kheng Raja Mogan, Tharishinny Lee, Jinn-Kye Ang, Zhi Zhong Li, Haitao Lee, Hiang Kwee |
| author_sort |
Chong, Carice |
| title |
Catalyst-on-hotspot nanoarchitecture: plasmonic focusing of light onto co-photocatalyst for efficient light-to-chemical transformation |
| title_short |
Catalyst-on-hotspot nanoarchitecture: plasmonic focusing of light onto co-photocatalyst for efficient light-to-chemical transformation |
| title_full |
Catalyst-on-hotspot nanoarchitecture: plasmonic focusing of light onto co-photocatalyst for efficient light-to-chemical transformation |
| title_fullStr |
Catalyst-on-hotspot nanoarchitecture: plasmonic focusing of light onto co-photocatalyst for efficient light-to-chemical transformation |
| title_full_unstemmed |
Catalyst-on-hotspot nanoarchitecture: plasmonic focusing of light onto co-photocatalyst for efficient light-to-chemical transformation |
| title_sort |
catalyst-on-hotspot nanoarchitecture: plasmonic focusing of light onto co-photocatalyst for efficient light-to-chemical transformation |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/174653 |
| _version_ |
1800916199116111872 |