Three-dimensional (3D) sensors selectively measure the applied force in a particular direction through the designed shape. However, such a fixed sensor design incurs a relatively low sensitivity and narrow measurement range to forces applied from other directions. Here, we report a shape-reconfigurable electronic composite based on a stiffness-tunable polymer and a crack-based strain sensor. The stiffness-tunable polymer allows a high degree of freedom (DOF) in modifying the shape of the electronic composite in its flexible state, enabling the formation of various 3D structures. This modification involves shifting the neutral plane toward the electrode to prevent fractures in the embedded sensors. After modifying the shape of the soft and flexible electronic composite, the dramatically increased stiffness of the stiffness-tunable polymer enables the maintenance of the reconfigured shape of the electronic composite and amplifies the mechanical signal from the external force of the targeted direction by returning the neutral plane to the original position. We validated the reversible modification of the shape of the electronic composite by demonstrating the increase in sensitivity and measured range for targeted external forces (bending, pressing, and stretching) via sequential changes in the designed shapes (wire, spiral, and spring) compared to the initial shape. This facile approach for shape modification will provide an opportunity to realize versatile shape changes in rigid electronics for user purpose.
S. H., D. K., and J.-S. K. acknowledge financial support from an Ajou University research fund. This work was supported by funding from the NRF of Korea (grant no. 2021R1C1C1011872, 2022R1A2C2093100, RS-2023-00271830, and RS-2023-00277110). This work was also supported by the Korea Environment Industry & Technology Institute (KEITI) through the Digital Infrastructure Building Project for Monitoring, Surveying, and Evaluating the Environmental Health Program, funded by the Korea Ministry of Environment (MOE) (2021003330009). This research was supported by a grant (HK23C0057) from the National Rehabilitation Center Research Institute. This work was supported by a National Research Council of Science & Technology (NST) grant from the Korea government (MSIT) (CRC23021-000). This research was supported by the Nano & Material Technology Development Program through the National Research Foundation of Korea (NRF) funded by Ministry of Science and ICT (RS-2024-00403639). J.-H. Lee acknowledges financial support from the Ajou University research fund.
