Hitoshi Asahina scite author profile

L81after the annealing fit well with the displaced atom density profile determined by the Mont Carlo simulation.'2 Since the ion implanted H is strongly bound with Si defects as trigonal configurations,1' H atom showed the same distribution with that of the Si displaced atom density. Therefore, 40% of the implanted H atoms still exist in the Si layer in the trigonal configuration after annealing. This ratio of the residual H atom agreed well with the ratio determined by the APIMS at 600°C shown in Fig. 5. ConclusionsConditions for the delamination were studied using H implanted Si layer. Ion implantation and annealing conditions, such as temperature and time for the delamination were found. Delamination was observed in layers implanted at doses above 5.0 x 1016 ion/cm2. The delamination occurred at 485°C with an annealing for 10 mm. The delamination temperature could be reduced to 425 and 400°C when the annealing time was increased to 60 and 120 mm, respectively. ABSTRACT Topographic and frictional changes on the surface of a highly oriented pyrolytic graphite electrode in 1 M LiClO4 ethylene carbonate/ethylmethyl carbonate (1:1) electrolyte were examined during charge and discharge by in situ electrochemical atomic force microscopy and friction force microscopy simultaneously in real-time. Solid electrolyte interphase film formation commenced at approximately 2 V vs. Li/Lit and stable film formation with an island-like morphology was observed below approximately 0.9 V vs. Li/Li. Further experiments on a KS-44 graphite/polyvinylidene difluoride binder composite electrode showed similar phenomena.) unless CC License in place (see abstract). ecsdl.org/site/terms_use address. Redistribution subject to ECS terms of use (see 128.112.200.107 Downloaded on 2015-07-12 to IP ABSTRACT Electrolytes based on 1-ethyl-3-methylimidazolium cation (EMl) and either the hexafluorophosphate (EMIPF6) or tetrafluorborate (EMIBF4) anion in organic alkyl carbonate solvents have been evaluated for use in electrochemical capacitors. The conductivity, capacitance, limiting oxidation and reduction potentials, and thermal stability were assessed. High conductivity and capacitance values were found regardless of whether cyclic (high viscosity/high dielectric constant) or acyclic (low viscosity/low dielectric constant) alkyl carbonates were used. The best correlation with conductivity for the EMIPF6 salt was found to be the molecular weight (Koi/Mw) and to a lesser degree the viscosity (kl/) of the solvent. The high specific capacitance (130 F/g) and excellent stability (>3.5 V, >130°C) make these electrolytes well suited for use in electrochemical double-layer capacitors.

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Analysis of surface films on lithium in various organic electrolytes

Kominato

Yasukawa

Sato

et al. 1997

Journal of Power Sources

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Material balance in the O₂ electrode of Li–O₂ cells with a porous carbon electrode and TEGDME-based electrolytes

Asahina

Matsuda

et al. 2020

RSC Adv.

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Effect of Electrolyte Filling Technology on the Performance of Porous Carbon Electrode-Based Lithium-Oxygen Batteries

Matsuda

Yamaguchi

Yasukawa

et al. 2021

ACS Appl. Energy Mater.

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Although the theoretical energy densities of lithium-oxygen batteries (LOBs) far exceed those of lithium-ion batteries, the practical values of the LOBs are usually much lower because of the use of large electrolyte excesses. Thus, to realize LOBs with a high practical energy density, the electrolyte amount should be minimized without compromising their performance. To address this challenge, we herein investigate the influence of several electrolyte filling techniques on the performance of LOBs, revealing that the battery discharge/charge profiles are strongly influenced by the uniformity of electrolyte distribution in the porous carbon electrode. The obtained results show the importance of electrolyte filling technology for realization of practical high-energy-density LOBs and facilitate their further development.

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Hitoshi Asahina

In Situ Electrochemical Atomic Force Microscope Study on Graphite Electrodes

Analysis of surface films on lithium in various organic electrolytes

Material balance in the O₂ electrode of Li–O₂ cells with a porous carbon electrode and TEGDME-based electrolytes

Effect of Electrolyte Filling Technology on the Performance of Porous Carbon Electrode-Based Lithium-Oxygen Batteries

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Hitoshi Asahina

In Situ Electrochemical Atomic Force Microscope Study on Graphite Electrodes

Analysis of surface films on lithium in various organic electrolytes

Material balance in the O2 electrode of Li–O2 cells with a porous carbon electrode and TEGDME-based electrolytes

Effect of Electrolyte Filling Technology on the Performance of Porous Carbon Electrode-Based Lithium-Oxygen Batteries

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Material balance in the O₂ electrode of Li–O₂ cells with a porous carbon electrode and TEGDME-based electrolytes