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1,606 results on '"Tian, Zhong-Qun"'

1. Towards a Unified Benchmark and Framework for Deep Learning-Based Prediction of Nuclear Magnetic Resonance Chemical Shifts

Author

Xu, Fanjie, Guo, Wentao, Wang, Feng, Yao, Lin, Wang, Hongshuai, Tang, Fujie, Gao, Zhifeng, Zhang, Linfeng, E, Weinan, Tian, Zhong-Qun, and Cheng, Jun

Subjects
Physics - Computational Physics, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Materials Science, Physics - Chemical Physics
Abstract

The study of structure-spectrum relationships is essential for spectral interpretation, impacting structural elucidation and material design. Predicting spectra from molecular structures is challenging due to their complex relationships. Herein, we introduce NMRNet, a deep learning framework using the SE(3) Transformer for atomic environment modeling, following a pre-training and fine-tuning paradigm. To support the evaluation of NMR chemical shift prediction models, we have established a comprehensive benchmark based on previous research and databases, covering diverse chemical systems. Applying NMRNet to these benchmark datasets, we achieve state-of-the-art performance in both liquid-state and solid-state NMR datasets, demonstrating its robustness and practical utility in real-world scenarios. This marks the first integration of solid and liquid state NMR within a unified model architecture, highlighting the need for domainspecific handling of different atomic environments. Our work sets a new standard for NMR prediction, advancing deep learning applications in analytical and structural chemistry., Comment: 23 pages, 6 figures

Published
2024

3. 1T′-transition metal dichalcogenide monolayers stabilized on 4H-Au nanowires for ultrasensitive SERS detection

Author

Li, Zijian, Zhai, Li, Zhang, Qinghua, Zhai, Wei, Li, Pai, Chen, Bo, Chen, Changsheng, Yao, Yao, Ge, Yiyao, Yang, Hua, Qiao, Panzhe, Kang, Jianing, Shi, Zhenyu, Zhang, An, Wang, Hongyi, Liang, Jinzhe, Liu, Jiawei, Guan, Zhiqiang, Liao, Lingwen, Neacșu, Vlad Andrei, Ma, Chen, Chen, Ye, Zhu, Ye, Lee, Chun-Sing, Ma, Lu, Du, Yonghua, Gu, Lin, Li, Jian-Feng, Tian, Zhong-Qun, Ding, Feng, and Zhang, Hua

Published
2024
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19. Plasmonic nanoreactors regulating selective oxidation by energetic electrons and nanoconfined thermal fields

Author

Zhan, Chao, Wang, Qiu-Xiang, Yi, Jun, Chen, Liang, Wu, De-Yin, Wang, Ye, Xie, Zhao-Xiong, Moskovits, Martin, and Tian, Zhong-Qun

Subjects
Chemical Sciences, Physical Chemistry, Affordable and Clean Energy
Abstract

Optimizing product selectivity and conversion efficiency are primary goals in catalysis. However, efficiency and selectivity are often mutually antagonistic, so that high selectivity is accompanied by low efficiency and vice versa. Also, just increasing the temperature is very unlikely to change the reaction pathway. Here, by constructing hierarchical plasmonic nanoreactors, we show that nanoconfined thermal fields and energetic electrons, a combination of attributes that coexist almost uniquely in plasmonic nanostructures, can overcome the antagonism by regulating selectivity and promoting conversion rate concurrently. For propylene partial oxidation, they drive chemical reactions by not only regulating parallel reaction pathways to selectively produce acrolein but also reducing consecutive process to inhibit the overoxidation to CO2, resulting in valuable products different from thermal catalysis. This suggests a strategy to rationally use plasmonic nanostructures to optimize chemical processes, thereby achieving high yield with high selectivity at lower temperature under visible light illumination.

Published
2021

23. Disentangling charge carrier from photothermal effects in plasmonic metal nanostructures.

Author

Zhan, Chao, Liu, Bo-Wen, Huang, Yi-Fan, Hu, Shu, Ren, Bin, Moskovits, Martin, and Tian, Zhong-Qun

Abstract

Plasmon-mediated chemical reactions (PMCRs) constitute a vibrant research field, advancing such goals as using sunlight to convert abundant precursors such as CO2 and water to useful fuels and chemicals. A key question in this burgeoning field which has not, as yet, been fully resolved, relates to the precise mechanism through which the energy absorbed through plasmonic excitation, ultimately drives such reactions. Among the multiple processes proposed, two have risen to the forefront: plasmon-increased temperature and generation of energetic charge carriers. However, it is still a great challenge to confidently separate these two effects and quantify their relative contribution to chemical reactions. Here, we describe a strategy based on the construction of a plasmonic electrode coupled with photoelectrochemistry, to quantitatively disentangle increased temperature from energetic charge carriers effects. A clear separation of the two effects facilitates the rational design of plasmonic nanostructures for efficient photochemical applications and solar energy utilization.

Published
2019

47. Impact of Surface Enhanced Raman Spectroscopy in Catalysis

Author

Stefancu, Andrei, Aizpurua, Javier, Alessandri, Ivano, Bald, Ilko, Baumberg, Jeremy J., Besteiro, Lucas V., Christopher, Phillip, Correa-Duarte, Miguel, de Nijs, Bart, Demetriadou, Angela, Frontiera, Renee R., Fukushima, Tomohiro, Halas, Naomi J., Jain, Prashant K., Kim, Zee Hwan, Kurouski, Dmitry, Lange, Holger, Li, Jian-Feng, Liz-Marzán, Luis M., Lucas, Ivan T., Meixner, Alfred J., Murakoshi, Kei, Nordlander, Peter, Peveler, William J., Quesada-Cabrera, Raul, Ringe, Emilie, Schatz, George C., Schlücker, Sebastian, Schultz, Zachary D., Tan, Emily Xi, Tian, Zhong-Qun, Wang, Lingzhi, Weckhuysen, Bert M., Xie, Wei, Ling, Xing Yi, Zhang, Jinlong, Zhao, Zhigang, Zhou, Ru-Yu, and Cortés, Emiliano

Abstract

Catalysis stands as an indispensable cornerstone of modern society, underpinning the production of over 80% of manufactured goods and driving over 90% of industrial chemical processes. As the demand for more efficient and sustainable processes grows, better catalysts are needed. Understanding the working principles of catalysts is key, and over the last 50 years, surface-enhanced Raman Spectroscopy (SERS) has become essential. Discovered in 1974, SERS has evolved into a mature and powerful analytical tool, transforming the way in which we detect molecules across disciplines. In catalysis, SERS has enabled insights into dynamic surface phenomena, facilitating the monitoring of the catalyst structure, adsorbate interactions, and reaction kinetics at very high spatial and temporal resolutions. This review explores the achievements as well as the future potential of SERS in the field of catalysis and energy conversion, thereby highlighting its role in advancing these critical areas of research.

Published
2024
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