用于无漂移离子电子传感的无蠕变聚电解质弹性体。

Creep-free polyelectrolyte elastomer for drift-free iontronic sensing.

作者信息

He Yunfeng, Cheng Yu, Yang Canhui, Guo Chuan Fei

机构信息

Shenzhen Key Laboratory of Soft Mechanics and Smart Manufacturing, Department of Mechanics and Aerospace Engineering, Southern University of Science and Technology, Shenzhen, P. R. China.

Department of Materials Science and Engineering, Southern University of Science and Technology, Shenzhen, P. R. China.

出版信息

Nat Mater. 2024 Aug;23(8):1107-1114. doi: 10.1038/s41563-024-01848-6. Epub 2024 Mar 21.

DOI:10.1038/s41563-024-01848-6

PMID:38514845

Abstract

Artificial pressure sensors often use soft materials to achieve skin-like softness, but the viscoelastic creep of soft materials and the ion leakage, specifically for ionic conductors, cause signal drift and inaccurate measurement. Here we report drift-free iontronic sensing by designing and copolymerizing a leakage-free and creep-free polyelectrolyte elastomer containing two types of segments: charged segments having fixed cations to prevent ion leakage and neutral slippery segments with a high crosslink density for low creep. We show that an iontronic sensor using the polyelectrolyte elastomer barely drifts under an ultrahigh static pressure of 500 kPa (close to its Young's modulus), exhibits a drift rate two to three orders of magnitude lower than that of the sensors adopting conventional ionic conductors and enables steady and accurate control for robotic manipulation. Such drift-free iontronic sensing represents a step towards highly accurate sensing in robotics and beyond.

摘要

人工压力传感器通常使用柔软材料来实现类似皮肤的柔软度，但柔软材料的粘弹性蠕变以及离子泄漏（特别是对于离子导体而言）会导致信号漂移和测量不准确。在此，我们报告了一种无漂移的离子电子传感技术，通过设计并共聚一种无泄漏且无蠕变的聚电解质弹性体来实现，该弹性体包含两种类型的链段：带有固定阳离子以防止离子泄漏的带电链段，以及具有高交联密度以实现低蠕变的中性光滑链段。我们展示了使用该聚电解质弹性体的离子电子传感器在500 kPa的超高静压力（接近其杨氏模量）下几乎不漂移，其漂移率比采用传统离子导体的传感器低两到三个数量级，并能够实现对机器人操作的稳定且精确的控制。这种无漂移的离子电子传感代表了向机器人技术及其他领域的高精度传感迈进的一步。

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用于无漂移离子电子传感的无蠕变聚电解质弹性体。

Creep-free polyelectrolyte elastomer for drift-free iontronic sensing.

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