A highly stretchable and sintering-free liquid metal composite conductor enabled by ferrofluid

Soft science Pub Date : 2023-10-16 DOI:10.20517/ss.2023.28
Maoyu Peng, Biao Ma, Guoqiang Li, Yong Liu, Yang Zhang, Xing Ma, Sheng Yan
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Abstract

Stretchable and highly conductive elastomers with intrinsically deformable liquid metal (LM) fillers exhibit promising potential in soft electronics, wearables, human-machine interfaces, and soft robotics. However, conventional LM-elastomer (LME) conductors require a high loading ratio of LM and the post-sintering to rupture LM particles to achieve electric conductivity, which results in high LM consumption and process complexity. In this work, we presented a straightforward and post-sintering-free method that utilizes magnetic aggregation to fabricate stretchable LME conductors. This was achieved by dispersing LM ferrofluid into the elastomer precursor, followed by applying the magnetic field to induce the aggregation and interconnection of the LM ferrofluid particles to form conductive pathways. This method not only simplifies the preparation of initially conductive LME but also reduces the LM loading ratio. The resulting conductive LME composites show high stretchability (up to 650% strain), high conductance stability, and magnetic responsiveness. The stretchable LME conductors were demonstrated in various applications, including the creation of flexible microcircuits, a magnetically controlled soft switch, and a soft hydrogel actuator for grasping tasks. We believe the stretchable LME conductors may find wide applications in electronic skins, soft sensors, and soft machines.
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一种由铁磁流体实现的高度可拉伸且无烧结的液态金属复合导体
具有内在可变形液态金属(LM)填充物的可拉伸和高导电性弹性体在软电子、可穿戴设备、人机界面和软机器人领域具有广阔的应用前景。然而,传统的LM-弹性体(LME)导体需要较高的LM载荷比,并且在烧结后使LM颗粒破裂以实现导电性,这导致了较高的LM消耗和工艺复杂性。在这项工作中,我们提出了一种直接的、无烧结后的方法,利用磁聚集来制造可拉伸的LME导体。这是通过将LM铁磁流体分散到弹性体前体中,然后施加磁场诱导LM铁磁流体颗粒聚集和互连以形成导电途径来实现的。该方法不仅简化了初始导电LME的制备,而且降低了LM加载比。所得到的导电LME复合材料具有高拉伸性(高达650%的应变),高电导稳定性和磁响应性。可拉伸LME导体在各种应用中进行了演示,包括创建柔性微电路,磁控软开关和用于抓取任务的软水凝胶执行器。我们相信可拉伸LME导体在电子皮肤、软传感器和软机器中有广泛的应用。
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