ポスター High Quality Factor Single-Crystal Diamond NEMS Cantilevers Fabricated by A Smart-Cut Method

Guo Chen (Research Center for Electronic and Optical Materials/Functional Materials Field/Ultra-wide Bandgap Semiconductors Group, National Institute for Materials Science) ; Wen Zhao (Research Center for Electronic and Optical Materials/Functional Materials Field/Ultra-wide Bandgap Semiconductors Group, National Institute for Materials Science) ; Keyun Gu (Research Center for Electronic and Optical Materials/Functional Materials Field/Ultra-wide Bandgap Semiconductors Group, National Institute for Materials Science) ; Satoshi Koizumi SAMURAI ORCID (Research Center for Electronic and Optical Materials/Functional Materials Field/Ultra-wide Bandgap Semiconductors Group, National Institute for Materials Science) ; Yasuo Koide SAMURAI ORCID (Research Center for Electronic and Optical Materials/Functional Materials Field/Next-generation Semiconductor Group, National Institute for Materials Science) ; Meiyong Liao SAMURAI ORCID (Research Center for Electronic and Optical Materials/Functional Materials Field/Ultra-wide Bandgap Semiconductors Group, National Institute for Materials Science)

NDNC2025_abstract_Chen.docx
Download file (317KB)
Download as zip (306KB)
コレクション

引用
Guo Chen, Wen Zhao, Keyun Gu, Satoshi Koizumi, Yasuo Koide, Meiyong Liao. High Quality Factor Single-Crystal Diamond NEMS Cantilevers Fabricated by A Smart-Cut Method. https://doi.org/10.48505/nims.5490

説明:

(abstract)

In this work, we investigated the resonance properties of SCD NEMS and their energy dissipation mechanisms at nanoscale. First, the SCD MEMS cantilevers with different length were fabricated by the smart-cut technique based on our previous work [4], as shown in Fig.1 (a). Oxygen etching was developed to fabricate nanometer-thick SCD NEMS. Through the high-temperature oxygen annealing (685°C, 80 hours) and reactive ion etching (RIE) for 10.5 minutes, the thickness of SCD MEMS resonators was successfully reduced from micro to nanoscale (sub 100 nm). As depicted in Fig.1 (b), the results shows that when the thickness of the SCD cantilevers was reduced from approximately 450 nm to 50 nm, the Q-factor decreased with the thickness from 105 to 104, achieving SCD NEMS cantilevers with a thickness of approximately 50 nm and a high Q-factor (> 50,000). The force sensitivity of the NEMS cantilever was 10 times improved to be ~10-17 N/Hz1/2. This work provides a new method for the fabrication of high sensitivity SCD NEMS sensors.

権利情報:

キーワード: Diamond, MEMS

刊行年月日:

出版者:

掲載誌:

会議: The 18th International Conference on New Diamond and Nano Carbons (2025-05-11 - 2025-05-15)

研究助成金:

原稿種別: 論文以外のデータ

MDR DOI: https://doi.org/10.48505/nims.5490

公開URL:

関連資料:

その他の識別子:

連絡先:

更新時刻: 2025-05-22 08:30:08 +0900

MDRでの公開時刻: 2025-05-22 08:23:11 +0900

ファイル名 サイズ
ファイル名 NDNC2025_abstract_Chen.docx (サムネイル)
application/vnd.openxmlformats-officedocument.wordprocessingml.document 		サイズ 317KB 詳細