PSI - Issue 80

Vinit Vijay Deshpande et al. / Procedia Structural Integrity 80 (2026) 327–338 Vinit V. Deshpande et al./ Structural Integrity Procedia 00 (2019) 000 – 000

338

12

Sangrós Giménez, C., Helmers, L., Schilde, C., Diener, A., and Kwade, A., 2020. Modeling the electrical conductive paths within all solid state battery electrodes. Chemical Engineering & Technology, 43(5), 819-829. Suzuki, K., Yataka, K., Okumiya, Y., Sakakibara, S., Sako, K., Mimura, H., and Inoue, Y., 2016. Rapid-response, widely stretchable sensor of aligned MWCNT/elastomer composites for human motion detection. Acs Sensors, 1(6), 817-825. Wang, Y., Xu, C., Jahnke, T., Verestek, W., Schmauder, S., and Spatz, J. P., 2022. Microstructural modeling and simulation of a carbon black based conductive polymer ─ a template for the virtual Design of a Composite Material. ACS omega, 7(33), 28820-28830. Yi, H., Wang, S., Mei, S., and Li, Z., 2024. Conductive polymer composites for resistive flexible strain sensors. Polymer, 307, 127286. Zha, J. W., Zhang, B., Li, R. K., and Dang, Z. M., 2016. High-performance strain sensors based on functionalized graphene nanoplates for damage monitoring. Composites Science and Technology, 123, 32-38. Zheng, Y., Li, Y., Dai, K., Wang, Y., Zheng, G., Liu, C., and Shen, C., 2018. A highly stretchable and stable strain sensor based on hybrid carbon nanofillers/polydimethylsiloxane conductive composites for large human motions monitoring. Composites Science and Technology, 156, 276 286.