論文雑誌「ACS Applied Nano Materials」のカバーアートを制作しました[産業技術総合研究所]
弊社で制作しました産業技術総合研究所 マセセ タイタス様のカバーアートが
アメリカ化学会発行の学術雑誌 ACS Applied Nano Materials
2021年 1月号のFront Coverに選ばれました。
Client
国立研究開発法人産業技術総合研究所
エネルギー・環境領域 電池技術研究部門
マセセ タイタス 様
エネルギー・環境領域 電池技術研究部門
マセセ タイタス 様
Journal
ACS Applied Nano Materials
January 22, 2021 Volume 4, Issue 1 Link
January 22, 2021 Volume 4, Issue 1 Link
Topological Defects and Unique Stacking Disorders in Honeycomb Layered Oxide
K2Ni2TeO6 Nanomaterials: Implications for Rechargeable Batteries
Titus Masese*, Yoshinobu Miyazaki*, Godwill Mbiti Kanyolo*, Teruo Takahashi, Miyu Ito,
Hiroshi Senoh*, and Tomohiro Saito*
ACS Applied Nano Materials 2021, 4, 1, 279-287 (Article)
Honeycomb layered oxides have risen to the top echelons of science with applications in diverse fields ranging from condensed matter physics, solid-state chemistry, materials science, and solid-state ionics to electrochemistry. A series of structural analyses conducted on honeycomb layered oxide K2Ni2TeO6 using aberration-corrected scanning transmission electron microscopy reveal hitherto unreported nanoscale topological defects. A three-dimensional atomic model is shown, with potassium (K), nickel (Ni), and tellurium (Te) in blue, green, and pink, respectively. Oxygen (O) atoms are shown in red. The artwork highlights curvatures and dislocations innate in pristine K2Ni2TeO6 associated with various functionalities of this class of materials, such as energy storage. Link
K2Ni2TeO6 Nanomaterials: Implications for Rechargeable Batteries
Titus Masese*, Yoshinobu Miyazaki*, Godwill Mbiti Kanyolo*, Teruo Takahashi, Miyu Ito,
Hiroshi Senoh*, and Tomohiro Saito*
ACS Applied Nano Materials 2021, 4, 1, 279-287 (Article)
Honeycomb layered oxides have risen to the top echelons of science with applications in diverse fields ranging from condensed matter physics, solid-state chemistry, materials science, and solid-state ionics to electrochemistry. A series of structural analyses conducted on honeycomb layered oxide K2Ni2TeO6 using aberration-corrected scanning transmission electron microscopy reveal hitherto unreported nanoscale topological defects. A three-dimensional atomic model is shown, with potassium (K), nickel (Ni), and tellurium (Te) in blue, green, and pink, respectively. Oxygen (O) atoms are shown in red. The artwork highlights curvatures and dislocations innate in pristine K2Ni2TeO6 associated with various functionalities of this class of materials, such as energy storage. Link