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Your search keyword '"Bai, Hua"' showing total 22 results
Start Over Author "Bai, Hua" Journal analytical chemistry
22 results on '"Bai, Hua"'

16. Plasmonic MoO2Nanospheres as a Highly Sensitive and Stable Non-Noble Metal Substrate for Multicomponent Surface-Enhanced Raman Analysis

Author

Zhang, Qiqi, Li, Xinshi, Yi, Wencai, Li, Wentao, Bai, Hua, Liu, Jingyao, and Xi, Guangcheng

Abstract

Semiconductor-based surface-enhanced Raman spectroscopy is getting more and more attention because of its great price advantage. One of the biggest obstacles to the large-scale application of it is the poor stability. Here, we report that plasmonic MoO2nanospheres can be used as a highly sensitive and stable semiconducting-substrate material for surface-enhanced Raman scattering (SERS). By using the MoO2nanospheres as Raman substrates, a series of typical compounds with high attention can be accurately detected. This new non-noble metal substrate material shows a very high detection limit of 10–8M, and exhibits great near-field enhancement with one of the highest enhancement factor of 4.8 × 106reported to date. More importantly, the oxide with intermediate valence displays unexpected ultrahigh stability, which can withstand the corrosion of strong acid and strong alkali as well as 150 °C high temperature oxidation in air. Moreover, the accurate detection of multicomponent samples was also successful on this substrate. These results show that some simple metal oxides with intermediate valence may become sensitive and stable SERS substrate materials due to their abundant free electrons and structure that easily causes hot spots.

Published
2024
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17. Alternative to Noble Metal Substrates: Metallic and Plasmonic Ti3O5Hierarchical Microspheres for Surface Enhanced Raman Spectroscopy

Author

Li, Yahui, Bai, Hua, Zhai, Junfeng, Yi, Wencai, Li, Junfang, Yang, Haifeng, and Xi, Guangcheng

Abstract

Compared with noble metals, improving the sensitivity of semiconducting surface-enhanced Raman scattering (SERS) substrates is of great significance to their fundamental research and practical application of Raman spectroscopy. In this paper, it is found that the SERS sensitivity is increased by 10 000 times by reducing the semiconducting TiO2microspheres to quasi-metallic Ti3O5microspheres. Its lowest detectable limit is up to 10–10M, which may be the best among the non-noble metal substrates and even reaches or exceeds certain Au/Ag nanostructures to the best of our knowledge. This new type of non-noble metal SERS substrate breaks through the bottleneck of poor stability of conventional semiconductor substrate and can withstand high temperature oxidation at 200 °C and strong acid–base corrosion without performance degradation. Benefiting from its excellent ability of visible-light photocatalytic degradation of organic molecules, the substrate can be reused. Moreover, the new material also exhibits excellent photothermal conversion properties.

Published
2019
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18. Highly Sensitive W18O49Mesocrystal Raman Scattering Substrate with Large-Area Signal Uniformity

Author

Ye, Yuting, Chen, Chao, Li, Wentao, Guo, Xingzhou, Yang, Haifeng, Guan, Haomin, Bai, Hua, Liu, Wei, and Xi, Guangcheng

Abstract

Although mesocrystals with ordered building units have great potential in many fields because of the large amount of organic molecules used as structure-directing agents during their synthesis process, severe matrix interference makes their surface-enhanced Raman scattering (SERS) properties rarely understood. Herein, a rapid (20 s) and green microwave synthetic route is developed for the 100 g scale preparation of plasmonic W18O49mesocrystals with no additives. The ultrathin (1.5 nm) and oxygen vacancy-rich W18O49nanowires as a building unit greatly improve the interface charge transfer, while the periodic mesocrystal structure significantly enhances the localized surface plasmon resonance effect and creates high-density electromagnetic hot spots among the nanowires. An outstanding enhancement factor of 1.2 × 107and an ultralow detectable limit of 10–11M are achieved, and the single-molecule imaging is also realized on this mesocrystal-based SERS substrate. Moreover, the relative standard deviation of the fabricated large-area (2.2 cm2) SERS substrate is only 6.8%.

Published
2021
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19. Moving MoO 2 /C Nanospheres with the Functions of Enrichment and Sensing for Online-High-Throughput SERS Detection.

Author

Song X, Yin M, Li J, Li Y, Yang H, Kong Q, Bai H, Xi G, and Mao L

Subjects
Microfluidics, Spectrum Analysis, Raman methods, Environmental Pollutants, Nanospheres chemistry
Abstract

The development of online surface-enhanced Raman spectroscopy (SERS) detection methods is crucial to achieving high-throughput efficiency. Herein, a non-noble-metal moving substrate that integrates the functions of enrichment and sensing is developed for the microfluidic online-high-throughput detection of pollutants. The lowest limit of detection of 1 × 10 -12 M and a Raman enhancement factor of 6.3 × 10 8 are obtained on the nanospheres. In a single detection channel, the analysis of 20 samples is achieved within 5 min, and the relative standard deviation of the signals is less than 6.8%. Compared with static SERS detection of fixed substrates, this dynamic SERS detection method greatly reduces the contamination memory effect of the analyte residue, enabling it to perform the sequential quantitative detection of samples with large concentration differences. Moreover, the current online SERS platform realizes the rapid quantitative detection of multicomponent samples.

Published
2022
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20. Highly Sensitive W 18 O 49 Mesocrystal Raman Scattering Substrate with Large-Area Signal Uniformity.

Author

Ye Y, Chen C, Li W, Guo X, Yang H, Guan H, Bai H, Liu W, and Xi G

Abstract

Although mesocrystals with ordered building units have great potential in many fields because of the large amount of organic molecules used as structure-directing agents during their synthesis process, severe matrix interference makes their surface-enhanced Raman scattering (SERS) properties rarely understood. Herein, a rapid (20 s) and green microwave synthetic route is developed for the 100 g scale preparation of plasmonic W 18 O 49 mesocrystals with no additives. The ultrathin (1.5 nm) and oxygen vacancy-rich W 18 O 49 nanowires as a building unit greatly improve the interface charge transfer, while the periodic mesocrystal structure significantly enhances the localized surface plasmon resonance effect and creates high-density electromagnetic hot spots among the nanowires. An outstanding enhancement factor of 1.2 × 10 7 and an ultralow detectable limit of 10 -11 M are achieved, and the single-molecule imaging is also realized on this mesocrystal-based SERS substrate. Moreover, the relative standard deviation of the fabricated large-area (2.2 cm 2 ) SERS substrate is only 6.8%.

Published
2021
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21. Alternative to Noble Metal Substrates: Metallic and Plasmonic Ti 3 O 5 Hierarchical Microspheres for Surface Enhanced Raman Spectroscopy.

Author

Li Y, Bai H, Zhai J, Yi W, Li J, Yang H, and Xi G

Abstract

Compared with noble metals, improving the sensitivity of semiconducting surface-enhanced Raman scattering (SERS) substrates is of great significance to their fundamental research and practical application of Raman spectroscopy. In this paper, it is found that the SERS sensitivity is increased by 10 000 times by reducing the semiconducting TiO 2 microspheres to quasi-metallic Ti 3 O 5 microspheres. Its lowest detectable limit is up to 10 -10 M, which may be the best among the non-noble metal substrates and even reaches or exceeds certain Au/Ag nanostructures to the best of our knowledge. This new type of non-noble metal SERS substrate breaks through the bottleneck of poor stability of conventional semiconductor substrate and can withstand high temperature oxidation at 200 °C and strong acid-base corrosion without performance degradation. Benefiting from its excellent ability of visible-light photocatalytic degradation of organic molecules, the substrate can be reused. Moreover, the new material also exhibits excellent photothermal conversion properties.

Published
2019
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22. Plasmonic MoO 2 Nanospheres as a Highly Sensitive and Stable Non-Noble Metal Substrate for Multicomponent Surface-Enhanced Raman Analysis.

Author

Zhang Q, Li X, Yi W, Li W, Bai H, Liu J, and Xi G

Abstract

Semiconductor-based surface-enhanced Raman spectroscopy is getting more and more attention because of its great price advantage. One of the biggest obstacles to the large-scale application of it is the poor stability. Here, we report that plasmonic MoO 2 nanospheres can be used as a highly sensitive and stable semiconducting-substrate material for surface-enhanced Raman scattering (SERS). By using the MoO 2 nanospheres as Raman substrates, a series of typical compounds with high attention can be accurately detected. This new non-noble metal substrate material shows a very high detection limit of 10 -8 M, and exhibits great near-field enhancement with one of the highest enhancement factor of 4.8 × 10 6 reported to date. More importantly, the oxide with intermediate valence displays unexpected ultrahigh stability, which can withstand the corrosion of strong acid and strong alkali as well as 150 °C high temperature oxidation in air. Moreover, the accurate detection of multicomponent samples was also successful on this substrate. These results show that some simple metal oxides with intermediate valence may become sensitive and stable SERS substrate materials due to their abundant free electrons and structure that easily causes hot spots.

Published
2017
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