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Tunable Fabrication of Conductive Ti3C2Tx MXenes via Inflating a Polyurethane Balloon for Acute Force Sensing.

Shengpeng HanZhilong DuanXiangqi MengQingbai ZhaoLinlin ZhangXiao OuyangNing MaHao WeiXinyue Zhang
Published in: Langmuir : the ACS journal of surfaces and colloids (2020)
Conductive microwrinkles present a superior performance in ultrasensitive sensing, smart controlling, as well as energy conservation because of their unique structures. These wrinkles are usually prepared by the deposition of a thin conductive stiff layer on a soft substrate under a certain strain. However, traditional conductive materials may encounter some deficiencies, such as fragility or poor dispersity, in any solvent. To promote the applicability of conductive microwrinkles, here, we adopt a new two-dimensional nanomaterial Ti3C2Tx MXene as the conductive stiff layer to construct the microwrinkles. By combining the spraying and inflating techniques, the hierarchical complex and delicate Ti3C2Tx-polyurethane (Ti3C2Tx-PU) microwrinkles have become facilely available. The characteristic wavelength and amplitude of the microwrinkles could be easily adjusted by altering the inflating height of the PU film or the spraying volume of the Ti3C2Tx solution. Because the as-prepared Ti3C2Tx wrinkles could sensitively generate deformation inducing a resistance change under a force, these structures are also assembled to detect the applied force. The Ti3C2Tx force sensors showed quick response to a tiny force and stable reliability over hundreds of cycles, which hold a promising potential to monitor or employ the microforce.
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