Si(111) Electrode/Electrolyte Interfacial Studied by <i>in-situ</i> Second Harmonic Generation<sup>†</sup>

Cai-he Liu; Rui-peng Bai; Yu Bai; Yuan Guo; Zhen Zhang

doi:10.1063/1674-0068/cjcp2007129

Chinese Journal of Chemical Physics, Volume. 33, Issue 5, 554(2020)

Si(111) Electrode/Electrolyte Interfacial Studied by in-situ Second Harmonic Generation^†

Cai-he Liu1...2, Rui-peng Bai1,2, Yu Bai1, Yuan Guo1,2, and Zhen Zhang12,* |Show fewer author(s)

¹Beijing National Laboratory of Molecular Sciences, State Key Laboratory of Molecular Reaction Dynamics, CAS Research/Education Center for Excellence in Molecular Sciences, Institute of Chemistry, Chinese Academy of Sciences, Beijing 100190, China

²University of the Chinese Academy of Sciences, Beijing 100049, China

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Fig. 1. Air/Si(111) interface rotation diagram

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Fig. 2. (a) SHG response curve of air/Si(111) interface with the pp polarization combination. The circles in the figure represent experimental data points and the solid line represents the fitted curves. (b) Polar map of the air/Si(111) interface. The red circle represents the intensity of the SHG signal and the polar axis represents the angle

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$(a) Cyclic voltammogram (CV) curve measured from the Si(111)/CH\begin{document}$ _3 $\end{document}CN system with a scan rate of 50 mV/s. (b) The Mott-Schottky diagram from the Si(111)/CH\begin{document}$ _3 $\end{document}CN system measured at 1500 Hz. The red dots are the experimental data, and the red solid line is obtained by fitting using Eq.(5). The experiment temperature was 298 K$

Fig. 3. (a) Cyclic voltammogram (CV) curve measured from the Si(111)/CH $Unknown environment 'document'$ CN system with a scan rate of 50 mV/s. (b) The Mott-Schottky diagram from the Si(111)/CH $Unknown environment 'document'$ CN system measured at 1500 Hz. The red dots are the experimental data, and the red solid line is obtained by fitting using Eq.(5). The experiment temperature was 298 K

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$The potential-dependent SHG intensity of the Si(111)/CH\begin{document}$ _3 $\end{document}CN system at azimuthal angles \begin{document}$ \phi $\end{document} = 0\begin{document}$ ^{\circ} $\end{document}, 30\begin{document}$ ^{\circ} $\end{document} and 60\begin{document}$ ^{\circ} $\end{document}. The red dots are the experimental data, and the black solid line is the fitting curve.$

Fig. 4. The potential-dependent SHG intensity of the Si(111)/CH $Unknown environment 'document'$ CN system at azimuthal angles $Unknown environment 'document'$ = 0 $Unknown environment 'document'$ , 30 $Unknown environment 'document'$ and 60 $Unknown environment 'document'$ . The red dots are the experimental data, and the black solid line is the fitting curve.

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Table 1. Fitting results of potential dependent SHG response for different polarization combinations at $ \phi $=30$ ^{\circ} $
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Table 1. Fitting results of potential dependent SHG response for different polarization combinations at $ \phi $=30$ ^{\circ} $

Table 2. Fitting results of potential dependent SHG response for different polarization combinations at $\phi$=0$^{\circ}$. The relative phase $\theta$ cannot be obtained by Eq.(6), and the values are not shown in the table.
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Table 2. Fitting results of potential dependent SHG response for different polarization combinations at $\phi$=0$^{\circ}$. The relative phase $\theta$ cannot be obtained by Eq.(6), and the values are not shown in the table.

Table 3. Fitting results of potential dependent SHG response for different polarization combinations at $ \phi $=60$ ^{\circ} $
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Table 3. Fitting results of potential dependent SHG response for different polarization combinations at $ \phi $=60$ ^{\circ} $

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Cai-he Liu, Rui-peng Bai, Yu Bai, Yuan Guo, Zhen Zhang. Si(111) Electrode/Electrolyte Interfacial Studied by in-situ Second Harmonic Generation^†[J]. Chinese Journal of Chemical Physics, 2020, 33(5): 554

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Paper Information

Received: Jul. 22, 2020

Accepted: Sep. 15, 2020

Published Online: Apr. 21, 2021

The Author Email: Zhang Zhen (zhangz@iccas.ac.cn)

DOI:10.1063/1674-0068/cjcp2007129

Topics

Nuclear physics

Particles and fields

Particle and nuclear astrophysics and cosmology

Table 1. Fitting results of potential dependent SHG response for different polarization combinations at $ \phi $=30$ ^{\circ} $

Table 1. Fitting results of potential dependent SHG response for different polarization combinations at $ \phi $=30$ ^{\circ} $

Table 2. Fitting results of potential dependent SHG response for different polarization combinations at $\phi$=0$^{\circ}$. The relative phase $\theta$ cannot be obtained by Eq.(6), and the values are not shown in the table.

Table 2. Fitting results of potential dependent SHG response for different polarization combinations at $\phi$=0$^{\circ}$. The relative phase $\theta$ cannot be obtained by Eq.(6), and the values are not shown in the table.

Table 3. Fitting results of potential dependent SHG response for different polarization combinations at $ \phi $=60$ ^{\circ} $

Table 3. Fitting results of potential dependent SHG response for different polarization combinations at $ \phi $=60$ ^{\circ} $

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