Enhancing electrical performance of inkjet-printed flexible strain sensors through substrate surface coating and multiphysics simulation
Enhancing electrical performance of inkjet-printed flexible strain sensors through substrate surface coating and multiphysics simulation
Inkjet-printed piezoresistive sensors are gaining popularity due to process compatibility with flexible substrates and the possibility of rapid on-demand fabrication. However, several technical challenges are frequently encountered, such as the compatibility of commercial inks with non-standard substrate materials and the necessity to enhance sensor sensitivity for application-specific performance. This study introduces a novel approach for improving the sensitivity of Mitsubishi silver nanoparticle inks on non-standard substrates by utilizing a two-layer surface coating of polyvinyl alcohol (PVA) and potassium chloride (KCl). In this work, non-standard substrates such as standard paper, glossy inkjet paper, and polyimide were coated prior to silver nanoparticle ink deposition using an office inkjet printer. The baseline resistance of non-standard substrate was compared with the Mitsubishi special media. The baseline resistance measurements revealed the lowest values on Mitsubishi special media (4.74–6.43 Ω), while polyimide exhibited significantly higher resistance (426–894 Ω) with high variability (standard deviation of 170.10 Ω), indicating substrate-dependent conductive performance. Further multiphysics simulation studies investigating the influence of various design features on the sensitivity were performed. The results indicate that the unit cell of the meander pattern (Z-shape) enhances sensitivity of 96.1 in a confined area, making it an optimal design choice for strain sensor applications. Key findings revealed that both length and spacing width significantly influence sensor performance. The two-layer coating and design influence on sensitivity provides critical insights for enhancing the electrical conductivity and piezoresistivity.
Inkjet Printing, Piezo-resistive, Silver Nanoparticles, Strain sensor, Gauge Factor, Coating
332-337
IET Conference Proceedings
Patil, Ishant G.
baed45a1-64d1-493a-bce2-5606e9491ec0
Bhima, Shirish
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Yeap, Phoebe Ying Xi
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Ch'ng, Shiau Ying
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Ling, Ting Yang
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Gan, Khong Wui
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Pu, Suan Hui
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1 March 2025
Patil, Ishant G.
baed45a1-64d1-493a-bce2-5606e9491ec0
Bhima, Shirish
fa943070-8960-48b5-8eb4-c123549fba8f
Yeap, Phoebe Ying Xi
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Ch'ng, Shiau Ying
ab3f59f3-4797-45c1-94f7-b656a84835a8
Ling, Ting Yang
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Gan, Khong Wui
b0c1e988-d375-4bbc-acdc-c77a6da1f904
Pu, Suan Hui
8b46b970-56fd-4a4e-8688-28668f648f43
Patil, Ishant G., Bhima, Shirish, Yeap, Phoebe Ying Xi, Ch'ng, Shiau Ying, Ling, Ting Yang, Gan, Khong Wui and Pu, Suan Hui
(2025)
Enhancing electrical performance of inkjet-printed flexible strain sensors through substrate surface coating and multiphysics simulation.
In International Conference on Green Energy, Computing and Intelligent Technology 2024 (GEn-CITy 2024).
vol. 2024,
IET Conference Proceedings.
.
(doi:10.1049/icp.2025.0275).
Record type:
Conference or Workshop Item
(Paper)
Abstract
Inkjet-printed piezoresistive sensors are gaining popularity due to process compatibility with flexible substrates and the possibility of rapid on-demand fabrication. However, several technical challenges are frequently encountered, such as the compatibility of commercial inks with non-standard substrate materials and the necessity to enhance sensor sensitivity for application-specific performance. This study introduces a novel approach for improving the sensitivity of Mitsubishi silver nanoparticle inks on non-standard substrates by utilizing a two-layer surface coating of polyvinyl alcohol (PVA) and potassium chloride (KCl). In this work, non-standard substrates such as standard paper, glossy inkjet paper, and polyimide were coated prior to silver nanoparticle ink deposition using an office inkjet printer. The baseline resistance of non-standard substrate was compared with the Mitsubishi special media. The baseline resistance measurements revealed the lowest values on Mitsubishi special media (4.74–6.43 Ω), while polyimide exhibited significantly higher resistance (426–894 Ω) with high variability (standard deviation of 170.10 Ω), indicating substrate-dependent conductive performance. Further multiphysics simulation studies investigating the influence of various design features on the sensitivity were performed. The results indicate that the unit cell of the meander pattern (Z-shape) enhances sensitivity of 96.1 in a confined area, making it an optimal design choice for strain sensor applications. Key findings revealed that both length and spacing width significantly influence sensor performance. The two-layer coating and design influence on sensitivity provides critical insights for enhancing the electrical conductivity and piezoresistivity.
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e-pub ahead of print date: 17 January 2025
Published date: 1 March 2025
Keywords:
Inkjet Printing, Piezo-resistive, Silver Nanoparticles, Strain sensor, Gauge Factor, Coating
Identifiers
Local EPrints ID: 501832
URI: http://eprints.soton.ac.uk/id/eprint/501832
PURE UUID: c04d10c4-4b8a-4adf-89a4-e615be978587
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Date deposited: 10 Jun 2025 18:18
Last modified: 03 Sep 2025 02:10
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Contributors
Author:
Ishant G. Patil
Author:
Shirish Bhima
Author:
Phoebe Ying Xi Yeap
Author:
Ting Yang Ling
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