Your search keyword '"Zhou, Ru-Yu"' showing total 4 results

1. Unraveling the energy storage mechanism in graphene-based nonaqueous electrochemical capacitors by gap-enhanced Raman spectroscopy.

Author

Yin, Xiao-Ting, You, En-Ming, Zhou, Ru-Yu, Zhu, Li-Hong, Wang, Wei-Wei, Li, Kai-Xuan, Wu, De-Yin, Gu, Yu, Li, Jian-Feng, Mao, Bing-Wei, and Yan, Jia-Wei

Subjects

SUPERCAPACITORS, ENERGY storage, RAMAN spectroscopy, SURFACE plasmons, ION exchange (Chemistry), SUPERCAPACITOR electrodes, BAND gaps

Abstract

Graphene has been extensively utilized as an electrode material for nonaqueous electrochemical capacitors. However, a comprehensive understanding of the charging mechanism and ion arrangement at the graphene/electrolyte interface remain elusive. Herein, a gap-enhanced Raman spectroscopic strategy is designed to characterize the dynamic interfacial process of graphene with an adjustable number of layers, which is based on synergistic enhancement of localized surface plasmons from shell-isolated nanoparticles and a metal substrate. By employing such a strategy combined with complementary characterization techniques, we study the potential-dependent configuration of adsorbed ions and capacitance curves for graphene based on the number of layers. As the number of layers increases, the properties of graphene transform from a metalloid nature to graphite-like behavior. The charging mechanism shifts from co-ion desorption in single-layer graphene to ion exchange domination in few-layer graphene. The increase in area specific capacitance from 64 to 145 µF cm–2 is attributed to the influence on ion packing, thereby impacting the electrochemical performance. Furthermore, the potential-dependent coordination structure of lithium bis(fluorosulfonyl) imide in tetraglyme ([Li(G4)][FSI]) at graphene/electrolyte interface is revealed. This work adds to the understanding of graphene interfaces with distinct properties, offering insights for optimization of electrochemical capacitors. Graphene is widely used as an electrode material but the understanding of its interface with electrolyte remains elusive. Here, authors employ gap-enhanced Raman spectroscopy and find that the charging mechanism shifts from co-ion desorption to ion exchange as the number of graphene layers increase. [ABSTRACT FROM AUTHOR]

Published

2024

2. Resolving nanostructure and chemistry of solid-electrolyte interphase on lithium anodes by depth-sensitive plasmon-enhanced Raman spectroscopy.

Author

Gu, Yu, You, En-Ming, Lin, Jian-De, Wang, Jun-Hao, Luo, Si-Heng, Zhou, Ru-Yu, Zhang, Chen-Jie, Yao, Jian-Lin, Li, Hui-Yang, Li, Gen, Wang, Wei-Wei, Qiao, Yu, Yan, Jia-Wei, Wu, De-Yin, Liu, Guo-Kun, Zhang, Li, Li, Jian-Feng, Xu, Rong, Tian, Zhong-Qun, and Cui, Yi

Subjects

RAMAN spectroscopy, SERS spectroscopy, COPPER, SURFACE plasmons, GOLD nanoparticles, ANODES, FLUOROETHYLENE

Abstract

The solid-electrolyte interphase (SEI) plays crucial roles for the reversible operation of lithium metal batteries. However, fundamental understanding of the mechanisms of SEI formation and evolution is still limited. Herein, we develop a depth-sensitive plasmon-enhanced Raman spectroscopy (DS-PERS) method to enable in-situ and nondestructive characterization of the nanostructure and chemistry of SEI, based on synergistic enhancements of localized surface plasmons from nanostructured Cu, shell-isolated Au nanoparticles and Li deposits at different depths. We monitor the sequential formation of SEI in both ether-based and carbonate-based dual-salt electrolytes on a Cu current collector and then on freshly deposited Li, with dramatic chemical reconstruction. The molecular-level insights from the DS-PERS study unravel the profound influences of Li in modifying SEI formation and in turn the roles of SEI in regulating the Li-ion desolvation and the subsequent Li deposition at SEI-coupled interfaces. Last, we develop a cycling protocol that promotes a favorable direct SEI formation route, which significantly enhances the performance of anode-free Li metal batteries. The solid-electrolyte interphase is crucial for most batteries, but its characterization is challenging. Here, authors develop a depth-sensitive plasmon-enhanced Raman spectroscopy method to enable in-situ and nondestructive resolving of its structure and chemistry as well as formation mechanisms. [ABSTRACT FROM AUTHOR]

Published

2023

3. In situ electrochemical Raman spectroscopy and ab initio molecular dynamics study of interfacial water on a single-crystal surface.

Author

Wang, Yao-Hui, Li, Shunning, Zhou, Ru-Yu, Zheng, Shisheng, Zhang, Yue-Jiao, Dong, Jin-Chao, Yang, Zhi-Lin, Pan, Feng, Tian, Zhong-Qun, and Li, Jian-Feng

Published

2023

4. In situ Raman spectroscopy reveals the structure and dissociation of interfacial water.

Author

Wang, Yao-Hui, Zheng, Shisheng, Yang, Wei-Min, Zhou, Ru-Yu, He, Quan-Feng, Radjenovic, Petar, Dong, Jin-Chao, Li, Shunning, Zheng, Jiaxin, Yang, Zhi-Lin, Attard, Gary, Pan, Feng, Tian, Zhong-Qun, and Li, Jian-Feng

Abstract

Understanding the structure and dynamic process of water at the solid–liquid interface is an extremely important topic in surface science, energy science and catalysis1–3. As model catalysts, atomically flat single-crystal electrodes exhibit well-defined surface and electric field properties, and therefore may be used to elucidate the relationship between structure and electrocatalytic activity at the atomic level4,5. Hence, studying interfacial water behaviour on single-crystal surfaces provides a framework for understanding electrocatalysis6,7. However, interfacial water is notoriously difficult to probe owing to interference from bulk water and the complexity of interfacial environments8. Here, we use electrochemical, in situ Raman spectroscopic and computational techniques to investigate the interfacial water on atomically flat Pd single-crystal surfaces. Direct spectral evidence reveals that interfacial water consists of hydrogen-bonded and hydrated Na+ ion water. At hydrogen evolution reaction (HER) potentials, dynamic changes in the structure of interfacial water were observed from a random distribution to an ordered structure due to bias potential and Na+ ion cooperation. Structurally ordered interfacial water facilitated high-efficiency electron transfer across the interface, resulting in higher HER rates. The electrolytes and electrode surface effects on interfacial water were also probed and found to affect water structure. Therefore, through local cation tuning strategies, we anticipate that these results may be generalized to enable ordered interfacial water to improve electrocatalytic reaction rates.Interfacial water consists of hydrogen-bonded water and Na·H2O, its structure changes at hydrogen evolution reaction (HER) potentials, and when structurally ordered it aids interfacial electron transfer, resulting in higher HER rates. [ABSTRACT FROM AUTHOR]

Published

2021