論文雑誌「JPCC」のカバーアートを制作しました[京都大学]
弊社で制作しました京都大学 原瑶佑様のカバーアートが、
アメリカ化学会発行の学術雑誌 The Journal of Physical Chemistry C
2021年1月号に選ばれました。
Client
京都大学
理学研究科
原 瑶佑 様
理学研究科
原 瑶佑 様
Journal
The Journal of Physical Chemistry C
January 7, 2021 Volume 125, Issue 2 Link
January 7, 2021 Volume 125, Issue 2 Link
Tunable and Well-Defined Bimodal Porous Model Electrodes for Revealing Multiscale Structural Effects in the Nonaqueous Li–O2 Electrode Process
Yosuke Hara, Manai Ono, Shoichi Matsuda, Kazuki Nakanishi, Kazuyoshi Kanamori,
and Ken Sakaushi*
Porous architectures gave significant influence to various properties in the nonaqueous Li‒O2 electrode process, which is attracting considerable interest because of applications to reversible energy storage with high energy density. This Article shows the effect of multiscale porous structures of cathode materials in Li‒O2 electrochemistry. Firstly, this Article presents a new synthetic strategy to design stable bimodal macroporous electrodes, which enable to investigate the complicated effects of porous structures. Secondly, by introducing the obtained model electrodes into the Li‒O2 electrode process, the bimodal macroporous structure was unveiled to give considerable influence to the key properties such as the efficiency of redox-mediators, discharge overpotential, and cycling life, depending on the multiscale structural configurations. The rational design of spatial and architectural location and pore size of the porous structures is necessary for the optimization of the key properties in the Li‒O2 electrode process. View the article.
Yosuke Hara, Manai Ono, Shoichi Matsuda, Kazuki Nakanishi, Kazuyoshi Kanamori,
and Ken Sakaushi*
Porous architectures gave significant influence to various properties in the nonaqueous Li‒O2 electrode process, which is attracting considerable interest because of applications to reversible energy storage with high energy density. This Article shows the effect of multiscale porous structures of cathode materials in Li‒O2 electrochemistry. Firstly, this Article presents a new synthetic strategy to design stable bimodal macroporous electrodes, which enable to investigate the complicated effects of porous structures. Secondly, by introducing the obtained model electrodes into the Li‒O2 electrode process, the bimodal macroporous structure was unveiled to give considerable influence to the key properties such as the efficiency of redox-mediators, discharge overpotential, and cycling life, depending on the multiscale structural configurations. The rational design of spatial and architectural location and pore size of the porous structures is necessary for the optimization of the key properties in the Li‒O2 electrode process. View the article.
