One-Step Fabrication of 2.5D CuMoO<sub>x</sub> Interdigital Microelectrodes Using Numerically Controlled Electric Discharge Machining for Coplanar Micro-Supercapacitors

One-Step Fabrication of 2.5D CuMoO<sub>x</sub> Interdigital Microelectrodes Using Numerically Controlled Electric Discharge Machining for Coplanar Micro-Supercapacitors

With the increasing market demands for wearable and portable electronic devices, binary metal oxides (BMOs) with a remarkable capacity and good structure stability have been considered as a promising candidate for fabricating coplanar micro-supercapacitors (CMSCs), serving as the power source. Howev...

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Bibliographic Details
Main Authors: Shunqi Yang, Ri Chen, Fu Huang, Wenxia Wang, Igor Zhitomirsky
Format: Article
Language:English
Published: MDPI AG 2024-10-01
Series:Micromachines
Subjects:
coplanar micro-supercapacitors
numerically controlled electric discharging machining
binary metal oxides
machining voltage
CuMoO<sub>x</sub>
Online Access:https://www.mdpi.com/2072-666X/15/11/1319
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Summary:With the increasing market demands for wearable and portable electronic devices, binary metal oxides (BMOs) with a remarkable capacity and good structure stability have been considered as a promising candidate for fabricating coplanar micro-supercapacitors (CMSCs), serving as the power source. However, the current fabrication methods for BMO microelectrodes are complex, which greatly hinder their further development and application in BMO CMSCs. Herein, the one-step fabrication of 2.5D CuMoO<sub>x</sub>-based CMSCs (CuMoCMSCs) has been realized by numerically controlled electric discharge machining (NCEDM) for the first time. In addition, the controllable capacity of CuMoCMSCs has been achieved by adjusting the NCEDM-machining voltage. The CuMoCMSCs machined by a machining voltage of 60 V (CuMoCMSCs60) showed the best performance. The fabricated CuMoCMSCs60 with binary metal oxides could operate at an ultra-high scanning rate of 10 V s<sup>−1</sup>, and gained a capacity of 40.3 mF cm<sup>−2</sup> (1.1 mA cm<sup>−2</sup>), which is more than 4 times higher than that of MoO<sub>x</sub>-based CMSCs (MoCMSCs60) with a single metal oxide. This is because CuMoO<sub>x</sub> BMOs materials overcome the poor electroconductivity problem of the MoO<sub>x</sub> single metal oxide. This one-step and numerically controlled fabrication technique developed in this research opens a new vision for preparing BMO materials, BMO microelectrodes, and BMO microdevices in an environmental, automatic, and intelligent way.
ISSN:2072-666X

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