Performing chiral photodetection, photocatalysis or photochemical reactions at the molecular level has always been a nearly impossible task, due to the very low efficiency of the generated optical circular dichroism signals. On the contrary, chiral colloidal nanocrystals have been shown recently to offer a very large differential response to circularly polarized light. Such a response is able to generate hot-electrons with a very strong asymmetry, thus potentially able to perform the aforementioned tasks. In this paper, an intermediate picture is chosen, for which an achiral small assembly of identical particles triggered by a chiral molecule is able to generate large plasmon-induced circular dichroism (PICD), in turn able to generate the required asymmetry in the generation rates of hot-electrons. By performing Finite Difference Time Domain simulations based on the combination of a classical model of PICD generation and a quantum-based model of hot-electrons generation, the simple design of an achiral gold NPs’ dimer triggered by a chiral molecule located in the center and oriented with its transition electric dipole moment parallel to the dimer axis is shown to be able to generate a strong asymmetry in its HEs’ generation response. The PICDs and related hot-electrons generation rates increase as a function of volume, surface, respectively, of the considered systems, thereby providing a way to trigger chemical reactions.
Published in | American Journal of Nanosciences (Volume 7, Issue 4) |
DOI | 10.11648/j.ajn.20210704.11 |
Page(s) | 59-65 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2021. Published by Science Publishing Group |
Plasmon, Chirality, Hot Electrons, Molecule
[1] | Alexander O. Govorov “Plasmon-Induced Circular Dichroism of a Chiral Molecule in the Vicinity of Metal Nanocrystals. Application to Various Geometries”. Journal of Physical Chemistry C, 115 (16): 7914–7923, 2011. |
[2] | Alexander O. Govorov and Zhiyuan Fan “Theory of chiral plasmonic nanostructures comprising metal nanocrystals and chiral molecular media.”. Chem Phys Chem, 13 (10): 2551–2560, 2012. |
[3] | Wenhe Wang, Fengxia Wu, Yanqun Zhang, Wenli Wei, Wenxin Niu, Guobao Xu, and Guobao Xu “Boosting Chiral Amplification in Plasmon-Coupled Circular Dichroism Using Discrete Silver Nanorods as Amplifiers”. Chemical Communications, 57: 7390–7393, 2021. |
[4] | Yun Wen, Meng-Qi He, Yong-Liang Yu, and Jian-Hua Wang “Biomolecule mediated chiral nanostructures a review of chiral mechanism and application”. Advances in Colloid and Interface Science, 289: 102376, 2021. |
[5] | Zhijian Hu, Dejing Meng, Feng Lin, Feng Lin, Xing Zhu, Zheyu Fang, and Xiaochun Wu “Plasmonic Circular Dichroism of Gold Nanoparticle Based Nanostructures”. Advanced Optical Materials, 7 (10): 1801590, 2019. |
[6] | Lucas V. Besteiro, Hui Zhang, Hui Zhang, Jérôme Plain, Gil Markovich, Zhiming Wang, Zhiming Wang, and Alexander O. Govorov “Aluminum Nanoparticles with Hot Spots for Plasmon-Induced Circular Dichroism of Chiral Molecules in the UV Spectral Interval”. Advanced Optical Materials, 5 (16): 1700069, 2017. |
[7] | Ben M. Maoz, Yulia Chaikin, Alexander B. Tesler, Omri Bar Elli, Zhiyuan Fan, Alexander O. Govorov, and Gil Markovich “Amplification of chiroptical activity of chiral biomolecules by surface plasmons.” Nano Letters, 13 (3): 1203–1209, 2013. |
[8] | H Atwater and A Polman “Plasmonics for improved photovoltaic devices”. Nature Mater, 9: 205–213, 2010. |
[9] | C Clavero “Plasmon-induced hot-electron generation at nanoparticle/metal-oxide interfaces for photovoltaic and photocatalytic devices”. Nature Photon, 8: 95–103, 2014. |
[10] | Scott K. Cushing and Nianqiang Wu “Progress and Perspectives of Plasmon-Enhanced Solar Energy Conversion”. The Journal of Physical Chemistry Letters, 7 (4): 666–675, 2016. |
[11] | Narima Eerqing, Aneeth Kakkanattu, Aneeth Kakkanattu, Shahin Ghamari, and Frank Vollmer “Review of optical sensing and manipulation of chiral molecules and nanostructures with focus on plasmonic enhancements”. Optics Express, 29 (8): 12543–12579, 2021. |
[12] | Larousse Khosravi Khorashad, Lucas V. Besteiro, Miguel A. Correa-Duarte, Sven Burger, Zhiming Wang, and Alexander O. Govorov “Hot Electrons Generated in Chiral Plasmonic Nanocrystals as a Mechanism for Surface Photochemistry and Chiral Growth.”. Journal of the American Chemical Society, 142 (9): 4193–4205, 2020. |
[13] | Mark L. Brongersma, Naomi J. Halas, and Peter Nordlander “Plasmon-induced hot carrier science and technology”. Nature Nanotechnology, 10: 25–34, 2015. |
[14] | Kaifeng Wu, Jacqueline Chen, James R Mcbride, and Tianquan Lian “Efficient hot electron transfer by a plasmon induced interfacial charge transfer transition”. Science, 349: 632–635, 2015. |
[15] | Linan Zhou, Dayne F. Swearer, Chao Zhang, Chao Zhang, Hossein Robatjazi, Hangqi Zhao, Luke Hen- derson, Luke C. Henderson, Liangliang Dong, Phillip Christopher, Emily A. Carter, Peter Nordlander, and Naomi J. Halas “Quantifying hot carrier and thermal contributions in plasmonic photocatalysis”. Science, 362 (72): 69, 2018. |
[16] | Yuchao Zhang, Shuai He, Shuai He, Wenxiao Guo, Yue Hu, Jiawei Huang, Jiawei Huang, Jiawei Huang, Justin R. Mulcahy, and Wei David Wei “Surface-Plasmon-Driven Hot Electron Photochemistry”. Chemical Reviews, 118 (6): 2927–2954, 2017. |
[17] | Yisong Zhu, Hongxing Xu, Peng Yu, and Zhiming Wang “Engineering plasmonic hot carrier dynamics toward efficient photodetection”. Applied physics reviews, 8: 021305, 2021. |
[18] | Calum Jack, Affar S. Karimullah, Ryan Tullius, Larousse Khosravi Khorashad, Marion Rodier, Brian Fitzpatrick, Laurence D. Barron, Nikolaj Gadegaard, Adrian J. Lapthorn, Vincent M. Rotello, Graeme Cooke, Alexander O. Govorov, and Malcolm Kadodwala “Spatial control of chemical processes on nanostructures through nanolocalized water heating.”. Nature Communications, 7: 10946, 2016. |
[19] | Xu Shi, Kosei Ueno, Tomoya Oshikiri, Quan Sun, Keiji Sasaki, Hiroaki Misawa, Hiroaki Misawa, Hiroaki Misawa, and Hiroaki Misawa “Enhanced water splitting under modal strong coupling conditions”. Nature Nanotechnology, 13: 953–958, 2018. |
[20] | Shaunak Mukherjee, Florian Libisch, Nicolas Large, Oara Neumann, Lisa V. Brown, Jin Cheng, J. Britt Lassiter, Emily A. Carter, Peter Nordlander, and Naomi J. Halas “Hot Electrons Do the Impossible: Plasmon- Induced Dissociation of H2 on Au”. Nano Letters, 13 (1): 240–247, 2013. |
[21] | Tianji Liu, Lucas V. Besteiro, Tim Liedl, Miguel A. Correa-Duarte, Zhiming Wang, and Alexander O. Govorov “Chiral Plasmonic Nanocrystals for Generation of Hot Electrons: Toward Polarization-Sensitive Photochemistry.”. Nano Letters, 19 (2): 1395–1407, 2019. |
[22] | Alexander O. Govorov, Hui Zhang, Hui Zhang, and Yurii K. Gun’ko “Theory of Photoinjection of Hot Plasmonic Carriers from Metal Nanostructures into Semiconductors and Surface Molecules”. Journal of Physical Chemistry C, 117 (32): 16616–16631, 2013. |
[23] | Hui Zhang, Hui Zhang, and Alexander O. Govorov “Giant circular dichroism of a molecule in a region of strong plasmon resonances between two neighboring gold nanocrystals”. Physical Review B 87: 075410, 2013. |
[24] | Huilei Zhao, Xiaoyu Zheng, Xuhui Feng, and Ying Li “CO2 Reduction by Plasmonic Au Nanoparticle- Decorated TiO2 Photocatalyst with an Ultrathin Al2O3 Interlayer”. Journal of Physical Chemistry C, 122 (33): 18949–18956, 2018. |
[25] | Lucas V. Besteiro, Xiang-Tian Kong, Zhiming Wang, and Alexander O. Govorov. Theory of Plasmonic Excitations: Fundamentals and Applications in Photocatalysis. WILEY-VCH GmbH, 2021. |
[26] | Vivek V. Thacker, Lars O. Herrmann, Daniel O. Sigle, Tao Zhang, Tao Zhang, Tao Zhang, Tim Liedl, Jeremy J. Baumberg, and Ulrich F. Keyser “DNA origami-based assembly of gold nanoparticle dimers for surface-enhanced Raman scattering”. Nature Communications, 5: 3448, 2014. |
[27] | Suchetan Pal, Zhengtao Deng, Baoquan Ding, Hao Yan, and Yan Liu “DNA-Origami-Directed Self-Assembly of Discrete Silver-Nanoparticle Architectures”. Angewandte Chemie, 49 (15): 2700–2704, 2010. |
[28] | Anastasiya Puchkova, Carolin Vietz, Enrico Pibiri, Bettina Wünsch, Maria Sanz Paz, Guillermo P. Acuna, and Philip Tinnefeld “DNA Origami Nanoantennas with over 5000-fold Fluorescence Enhancement and Single- Molecule Detection at 25 µM.”. Nano Letters, 2015. |
[29] | X. T Kong, L V Besteiro, Z Wang, and A O Govorov “Plasmonic Chirality and Circular Dichroism in Bioassembled and Nonbiological Systems: Theoretical Background and Recent Progress”. Adv. Mater, 32: 1801790–1801790, 2020. |
[30] | Xiang-Tian Kong, Lucas V. Besteiro, Zhiming Wang, and Alexander O. Govorov “Plasmonic Chirality and Circular Dichroism in Bioassembled and Nonbiological Systems: Theoretical Background and Recent Progress.”. Advanced Materials, 32 (41): 1801790, 2018. |
[31] | Alexander O. Govorov, Zhiyuan Fan, Pedro Hernandez, Joseph M. Slocik, and Rajesh R. Naik “Theory of Circular Dichroism of Nanomaterials Comprising Chiral Molecules and Nanocrystals: Plasmon Enhancement, Dipole Interactions, and Dielectric Effects”. Nano Letters, 10 (4): 1374–1382, 2010. |
[32] | Maximilian J. Urban, Chenqi Shen, Xiang-Tian Kong, Chenggan Zhu, Alexander O. Govorov, Qiangbin Wang, Mario Hentschel, and Na Liu “Chiral Plasmonic Nanostructures Enabled by Bottom-Up Approaches.”. Annual Review of Physical Chemistry, 70 (1): 275–299, 2019. |
[33] | Qihui Ye, Q. H. Ye, Xudong Chen, X. D. Chen, Shihong Wang, Shijie Wang, Z. Y. Hu, Gang Song, and G. Song “Chirality-detecting–based chiral molecule-metal-chiral molecule structures”. EPL, 134: 27003, 2021. |
[34] | Robert W. Woody. Theory of Circular Dichroism of Proteins. In G. D. Fasman, editor, Circular Dichroism and the conformational analysis of biomolecules, pages 25–67, New York, 1996. Plenum. |
[35] | Lumerical Inc. |
[36] | Lucas V. Besteiro and Alexander O. Govorov “Amplified Generation of Hot Electrons and Quantum Surface Effects in Nanoparticle Dimers with Plasmonic Hot Spots”. Journal of Physical Chemistry C, 120 (34): 19329–19339, 2016. |
[37] | Anton Kuzyk, Ralf Jungmann, Guillermo P. Acuna, and Na Liu “DNA Origami Route for Nanophotonics”. ACS Photonics, 5 (4): 1151–1163, 2018. |
APA Style
Renaud Arthur Léon Vallée. (2021). Plasmon-induced Circular Dichroism and Asymmetric Hot-electrons Generation Triggered by a Chiral Molecule for Polarization-dependent Chemical Reactions. American Journal of Nanosciences, 7(4), 59-65. https://doi.org/10.11648/j.ajn.20210704.11
ACS Style
Renaud Arthur Léon Vallée. Plasmon-induced Circular Dichroism and Asymmetric Hot-electrons Generation Triggered by a Chiral Molecule for Polarization-dependent Chemical Reactions. Am. J. Nanosci. 2021, 7(4), 59-65. doi: 10.11648/j.ajn.20210704.11
AMA Style
Renaud Arthur Léon Vallée. Plasmon-induced Circular Dichroism and Asymmetric Hot-electrons Generation Triggered by a Chiral Molecule for Polarization-dependent Chemical Reactions. Am J Nanosci. 2021;7(4):59-65. doi: 10.11648/j.ajn.20210704.11
@article{10.11648/j.ajn.20210704.11, author = {Renaud Arthur Léon Vallée}, title = {Plasmon-induced Circular Dichroism and Asymmetric Hot-electrons Generation Triggered by a Chiral Molecule for Polarization-dependent Chemical Reactions}, journal = {American Journal of Nanosciences}, volume = {7}, number = {4}, pages = {59-65}, doi = {10.11648/j.ajn.20210704.11}, url = {https://doi.org/10.11648/j.ajn.20210704.11}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajn.20210704.11}, abstract = {Performing chiral photodetection, photocatalysis or photochemical reactions at the molecular level has always been a nearly impossible task, due to the very low efficiency of the generated optical circular dichroism signals. On the contrary, chiral colloidal nanocrystals have been shown recently to offer a very large differential response to circularly polarized light. Such a response is able to generate hot-electrons with a very strong asymmetry, thus potentially able to perform the aforementioned tasks. In this paper, an intermediate picture is chosen, for which an achiral small assembly of identical particles triggered by a chiral molecule is able to generate large plasmon-induced circular dichroism (PICD), in turn able to generate the required asymmetry in the generation rates of hot-electrons. By performing Finite Difference Time Domain simulations based on the combination of a classical model of PICD generation and a quantum-based model of hot-electrons generation, the simple design of an achiral gold NPs’ dimer triggered by a chiral molecule located in the center and oriented with its transition electric dipole moment parallel to the dimer axis is shown to be able to generate a strong asymmetry in its HEs’ generation response. The PICDs and related hot-electrons generation rates increase as a function of volume, surface, respectively, of the considered systems, thereby providing a way to trigger chemical reactions.}, year = {2021} }
TY - JOUR T1 - Plasmon-induced Circular Dichroism and Asymmetric Hot-electrons Generation Triggered by a Chiral Molecule for Polarization-dependent Chemical Reactions AU - Renaud Arthur Léon Vallée Y1 - 2021/10/15 PY - 2021 N1 - https://doi.org/10.11648/j.ajn.20210704.11 DO - 10.11648/j.ajn.20210704.11 T2 - American Journal of Nanosciences JF - American Journal of Nanosciences JO - American Journal of Nanosciences SP - 59 EP - 65 PB - Science Publishing Group SN - 2575-4858 UR - https://doi.org/10.11648/j.ajn.20210704.11 AB - Performing chiral photodetection, photocatalysis or photochemical reactions at the molecular level has always been a nearly impossible task, due to the very low efficiency of the generated optical circular dichroism signals. On the contrary, chiral colloidal nanocrystals have been shown recently to offer a very large differential response to circularly polarized light. Such a response is able to generate hot-electrons with a very strong asymmetry, thus potentially able to perform the aforementioned tasks. In this paper, an intermediate picture is chosen, for which an achiral small assembly of identical particles triggered by a chiral molecule is able to generate large plasmon-induced circular dichroism (PICD), in turn able to generate the required asymmetry in the generation rates of hot-electrons. By performing Finite Difference Time Domain simulations based on the combination of a classical model of PICD generation and a quantum-based model of hot-electrons generation, the simple design of an achiral gold NPs’ dimer triggered by a chiral molecule located in the center and oriented with its transition electric dipole moment parallel to the dimer axis is shown to be able to generate a strong asymmetry in its HEs’ generation response. The PICDs and related hot-electrons generation rates increase as a function of volume, surface, respectively, of the considered systems, thereby providing a way to trigger chemical reactions. VL - 7 IS - 4 ER -