AI Article Synopsis
- - This study focuses on the performance of switches made from multiwalled carbon nanotubes, showcasing low operational voltages and a unique nanoassembly method for testing individual devices without interference.
- - The researchers analyze critical factors like device stability, repeatability, and potential failure issues, while also introducing a technique for modifying the physical properties of the nanotubes through current-driven shell etching.
- - Advanced computational models are used to predict device performance under stress and to explore how nanowire constructs can achieve greater stable movement compared to larger microscale devices.
Article Abstract
We report on the electromechanical actuation and switching performance of nanoconstructs involving doubly clamped, individual multiwalled carbon nanotubes. Batch-fabricated, three-state switches with low ON-state voltages (6.7 V average) are demonstrated. A nanoassembly architecture that permits individual probing of one device at a time without crosstalk from other nanotubes, which are originally assembled in parallel, is presented. Experimental investigations into device performance metrics such as hysteresis, repeatability and failure modes are presented. Furthermore, current-driven shell etching is demonstrated as a tool to tune the nanomechanical clamping configuration, stiffness, and actuation voltage of fabricated devices. Computational models, which take into account the nonlinearities induced by stress-stiffening of 1-D nanowires at large deformations, are presented. Apart from providing accurate estimates of device performance, these models provide new insights into the extension of stable travel range in electrostatically actuated nanowire-based constructs as compared to their microscale counterparts.
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| http://dx.doi.org/10.1021/nn900436x | DOI Listing |
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