A multifunctional flexible sensor based on PI-MXene/SrTiO3 hybrid aerogel for tactile perception

IF 33.2 1区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

The Innovation Pub Date : 2024-02-28 DOI:10.1016/j.xinn.2024.100596

Shihao Deng, Yue Li, Shengzhao Li, Shen Yuan, Hao Zhu, Ju Bai, Jingyi Xu, Lu Peng, Tie Li, Ting Zhang

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Abstract

The inadequacy of tactile perception systems in humanoid robotic manipulators limits the breadth of available robotic applications. Here, we designed a multifunctional flexible tactile sensor for robotic fingers that provides capabilities similar to those of human skin sensing modalities. This sensor utilizes a novel PI-MXene/SrTiO hybrid aerogel developed as a sensing unit with the additional abilities of electromagnetic transmission and thermal insulation to adapt to certain complex environments. Moreover, polyimide (PI) provides a high-strength skeleton, MXene realizes a pressure-sensing function, and MXene/SrTiO achieves both thermoelectric and infrared radiation response behaviors. Furthermore, via the pressure response mechanism and unsteady-state heat transfer, these aerogel-derived flexible sensors realize multimodal sensing and recognition capabilities with minimal cross-coupling. They can differentiate among 13 types of hardness and four types of material from objects with accuracies of 94% and 85%, respectively, using a decision tree algorithm. In addition, based on the infrared radiation-sensing function, a sensory array was assembled, and different shapes of objects were successfully recognized. These findings demonstrate that this PI-MXene/SrTiO aerogel provides a new concept for expanding the multifunctionality of flexible sensors such that the manipulator can more closely reach the tactile level of the human hand. This advancement reduces the difficulty of integrating humanoid robots and provides a new breadth of application scenarios for their possibility.

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基于 PI-MXene/SrTiO3 混合气凝胶的多功能柔性触觉传感器

仿人机器人操纵器中触觉感知系统的不足限制了机器人应用的广度。在这里，我们为机器人手指设计了一种多功能柔性触觉传感器，它具有与人类皮肤传感模式类似的功能。这种传感器采用了一种新型 PI-MXene/SrTiO 混合气凝胶作为传感单元，并具有电磁传输和隔热的额外能力，以适应某些复杂的环境。此外，聚酰亚胺（PI）提供了高强度骨架，MXene 实现了压力传感功能，MXene/SrTiO 实现了热电和红外辐射响应行为。此外，通过压力响应机制和非稳态传热，这些气凝胶衍生柔性传感器以最小的交叉耦合实现了多模态传感和识别功能。利用决策树算法，它们可以区分物体的 13 种硬度和 4 种材料，准确率分别达到 94% 和 85%。此外，基于红外辐射传感功能，还组装了一个传感阵列，并成功识别了不同形状的物体。这些研究结果表明，PI-MXene/SrTiO 气凝胶为扩展柔性传感器的多功能性提供了一个新概念，使机械手能更接近人手的触觉水平。这一进步降低了集成仿人机器人的难度，并为其提供了新的广泛应用场景。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

The Innovation MULTIDISCIPLINARY SCIENCES-

CiteScore

38.30

自引率

1.20%

发文量

134

审稿时长

6 weeks

期刊介绍： The Innovation is an interdisciplinary journal that aims to promote scientific application. It publishes cutting-edge research and high-quality reviews in various scientific disciplines, including physics, chemistry, materials, nanotechnology, biology, translational medicine, geoscience, and engineering. The journal adheres to the peer review and publishing standards of Cell Press journals. The Innovation is committed to serving scientists and the public. It aims to publish significant advances promptly and provides a transparent exchange platform. The journal also strives to efficiently promote the translation from scientific discovery to technological achievements and rapidly disseminate scientific findings worldwide. Indexed in the following databases, The Innovation has visibility in Scopus, Directory of Open Access Journals (DOAJ), Web of Science, Emerging Sources Citation Index (ESCI), PubMed Central, Compendex (previously Ei index), INSPEC, and CABI A&I.