Miniaturized or even microscale generators that could effectively and persistently converse weak and random mechanical energy from environments into electricity promise huge applications in the internet of things, sensor networks, big data, personal health systems, artificial intelligence, etc. However, such generators havent appeared yet because either the current density, or persistence, or both of all reported attempts were too low to real applications. Here, we demonstrate a superlubric Schottky generator (SLSG) in microscale such that the sliding contact between a microsized graphite flake and an n-type silicon is in a structural superlubric state, namely a ultralow friction and wearless state. This SLSG generates a stable electrical current at a high density (~119 Am-2) for at least 5,000 cycles. Since no current decay and wear were observed during the entire experiment, we believe that the real persistence of the SLSG should be enduring or substantively unlimited. In addition, the observed results exclude the mechanism of friction excitation in our Schottky generator, and provide the first experimental support of the conjectured mechanism of depletion layer establishment and destruction (DLED). Furthermore, we demonstrate a physical process of the DLED mechanism by the use of a quasi-static semiconductor finite element simulation. Our work may guide and accelerate future SLSGs into real applications.
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