Huggins A. Robert: Advanced batteries—materials science aspects

Holze, R.

doi:10.1007/s10008-013-2093-4

Cited by 2 publications

(3 citation statements)

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“…Some of the reduction peaks of the 1 st cycles correspond to the SEI formation on the electrode surface. The organic solvents composing the electrolyte partially react during the first discharge, generating the SEI, which acts as a protective layer against side reactions and enabling only lithium ions to cross it [21]. The SEI formation is also responsible for the initial irreversible capacity loss of the cell since Li + ions that are provided by the cathode during the first cycle are trapped inside this layer [22].…”

Section: Micro-structural Characterisationmentioning

confidence: 99%

Comparison of Porous Germanium Thin Films on SS and Mo as Anode for High-Performance LIBs

Diolaiti,

Andreoli,

Chauque

et al. 2023

IEEE Trans. Nanotechnology

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The increasing demand for high performance lithium ion batteries is pushing the research toward the development of new materials for electrodes. Our study focuses on the usage of Germanium as the active material for the negative electrode since it has a higher theoretical specific capacity than standard graphite-based electrodes. This research article provides insight into the electrochemical performance of thin films of Germanium deposited on metallic substrates and then nanostructured via electrochemical etching. Molybdenum and stainless steel are investigated as substrates and compared with regard to the performance of the resulting electrodes. The nanostructured Germanium electrodes show promising results, demonstrating a stable and high specific capacity for hundreds of cycles. The long-term stability of the cell together with a high rate capability proves the reliability of the cell engineered.

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Section: Micro-structural Characterisationmentioning

confidence: 99%

Comparison of Porous Germanium Thin Films on SS and Mo as Anode for High-Performance LIBs

Diolaiti,

Andreoli,

Chauque

et al. 2023

IEEE Trans. Nanotechnology

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“…The conversion reaction mechanism involves chemical transformation to form a new compound and the process is reversible. [7] Due to the uniqueness of the reversible reaction, selective adsorption (removal)/desorption (recovery) of ions can be achieved. At the same time, these materials such as Ag and Bi have high specific charge capacity, so they have high desalination capacity (SAC) (Scheme 1b).…”

Section: Introductionmentioning

confidence: 99%

“…In recent years, reversible electrochemical conversion has been reported to achieve selective removal and recovery of ions, overcoming the non‐selective defects of traditional CDI electro‐adsorption. The conversion reaction mechanism involves chemical transformation to form a new compound and the process is reversible [7] . Due to the uniqueness of the reversible reaction, selective adsorption (removal)/desorption (recovery) of ions can be achieved.…”

Section: Introductionmentioning

confidence: 99%

Reversible Electrochemical Conversion Reaction for Selective Ion Removal and Recovery

Yang,

Miao,

Zhang

2023

ChemElectroChem

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Capacitive deionization (CDI) is a green and pollution‐free emerging technology that can be used for ions removal and recovery from water. However, the traditional electro‐adsorption process to achieve ions removal faces the challenges of non‐selectivity, low efficiency and difficult ion recovery. In recent years, the conversion reaction has attracted wide attention due to its high selectivity, reversibility and excellent desalination ability for ions removal and recovery. This concept article will focus on the connotation and representative applications of conversion reactions that can be used for ion‐selective removal and recovery and put forward the perspectives and outlooks of conversion reactions.

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Huggins A. Robert: Advanced batteries—materials science aspects

Cited by 2 publications

References 0 publications

Comparison of Porous Germanium Thin Films on SS and Mo as Anode for High-Performance LIBs

Comparison of Porous Germanium Thin Films on SS and Mo as Anode for High-Performance LIBs

Reversible Electrochemical Conversion Reaction for Selective Ion Removal and Recovery

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