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Electrostatic in-plane structural superlubric actuator

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Abstract

Micro actuators are widely used in NEMS/MEMS for control and sensing. However, most are designed with suspended beams anchored at fixed points, causing two main issues: restricted actuated stroke and movement modes, and reduced lifespan due to fatigue from repeated beam deformation, contact wear and stiction. Here, we develop an electrostatic in-plane actuator leveraging structural superlubric sliding interfaces, characterized by zero wear, ultralow friction, and no fixed anchor. The actuator features a micro-scale graphite flake in structural superlubric contact with silicon dioxide tracks, reducing friction from edge defects. Using the charge injection method, the structural superlubric actuator not only achieves a maximum relative actuation stroke of 82.3% of the flake size by applying voltage to buried electrodes—3.4 times larger than previously reported, but also enables controllable reciprocating actuation by adjusting the form of the bias voltage. Additionally, no visible wear was observed at the structural superlubric interface after over 10,000 sliding cycles, indicating robust reliability. Our work presents a design concept for micro actuators with high performance and durability, potentially guiding the development of many structural superlubric micro-devices. Large stroke, long lifespan and durability are challenging in electrostatic in-plane micro actuators. Here, the authors exploit the structural superlubric sliding interfaces of a micro-scale graphite flake and the silicon dioxide track to achieve this goal.

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