Investigation of the reliability of nano-nickel/niobium oxide-based multilayer thin films deposited on polymer substrates for flexible electronic applications
Flexible electronics are attractive for a range of applications, such as wearable gadgets and personalized medicine, because of their flexibility, stretchability, and adaptability. However, the reliability of such devices, both mechanical and electrical, is a bottleneck for their widespread applicat...
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sg-ntu-dr.10356-1735472024-02-16T15:44:33Z Investigation of the reliability of nano-nickel/niobium oxide-based multilayer thin films deposited on polymer substrates for flexible electronic applications Sahay, Rahul Tu, Yen-Cheng Aziz, Izzat Budiman, Arief S. Tan, Cher Ming Lee, Pooi See Thomas, Olivier Raghavan, Nagarajan School of Materials Science and Engineering Engineering Multilayer Thin Films Flexible Electronics Flexible electronics are attractive for a range of applications, such as wearable gadgets and personalized medicine, because of their flexibility, stretchability, and adaptability. However, the reliability of such devices, both mechanical and electrical, is a bottleneck for their widespread application across different use-case scenarios. Here, we report the reliability of nickel-niobium oxide (crystalline-amorphous) sandwich nanolayers on a PI substrate (Ni-Nb2O5-PI) compared to pure nickel (Ni) nanolayers on a PI substrate (Ni-PI) as a potential candidate for electrodes or interconnects for flexible electronic or energy devices. A tailored rate-dependent bending failure/fracture test system was used to analyze the electrical resistance (oscillations) as a function of the loading cycles of the sample deposited on polyimide (PI) (the compliant substrate). Resistance oscillation amplitude during the rate-dependent bending failure/fracture test for Ni-PI (∼6%) was higher compared to that of Ni-Nb2O5-PI (∼2%), suggesting a low resistance change and consequently low mechanical deformation for Ni-Nb2O5-PI. Nanoindentation experiments were also performed to ascertain the hardness and reduced elastic modulus of the samples. Hardness of Ni-PI (∼1.4 GPa) was lower compared to that of Ni-Nb2O5-PI (∼2.4 GPa) suggesting high flow strength for Ni-Nb2O5-PI. Therefore, the incorporation of amorphous niobium oxide into samples otherwise composed of Ni nanolayers significantly improved their fatigue/fracture strength with a slight reduction in electrical conductivity with appreciably low resistance oscillation (amplitude) essential for operational reliability of flexible devices. We also demonstrated that the nickel-niobium oxide/polyimide stack was electrically/mechanically stable up to 500 K stress cycles at a bending radius of 8.5 mm. National Research Foundation (NRF) Published version We gratefully acknowledge co-funding provided by the National Research Foundation (NRF), Singapore through the Grant NRF2018-NRF-ANR042 (Street Art Nano) and the ANR (Agence Nationale de la Recherche) of the French government through the Grant ANR ANR18-CE09-003801 (Street Art Nano). The corresponding author (Nagarajan Raghavan) would also like to acknowledge the support of the research surplus funding from Singapore University of Technology and Design (SUTD) under grant no. RS-INSUR-00019-E0601-S00 for Open Access article publication fee charges. ASB gratefully acknowledges the Oregon Renewable Energy Center (OREC)'s support and resources provided through the Grant OREC/WIND titled “Novel Materials Coating for Wind Turbine Blades Protection and Deicing” at OregonTech. RS, ASB and NR also acknowledge support from the “Data-Driven Design of Mechanical properties in Metallic Layered Structures”. 2024-02-13T07:51:22Z 2024-02-13T07:51:22Z 2023 Journal Article Sahay, R., Tu, Y., Aziz, I., Budiman, A. S., Tan, C. M., Lee, P. S., Thomas, O. & Raghavan, N. (2023). Investigation of the reliability of nano-nickel/niobium oxide-based multilayer thin films deposited on polymer substrates for flexible electronic applications. Materials Advances, 4(15), 3257-3269. https://dx.doi.org/10.1039/d3ma00147d 2633-5409 https://hdl.handle.net/10356/173547 10.1039/d3ma00147d 2-s2.0-85165368708 15 4 3257 3269 en NRF2018-NRF-ANR042 Materials Advances © 2023 The Author(s). Published by the Royal Society of Chemistry. This article is licensed under a Creative Commons Attribution-NonCommercial 3.0 Unported Licence. application/pdf |
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Engineering Multilayer Thin Films Flexible Electronics |
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Engineering Multilayer Thin Films Flexible Electronics Sahay, Rahul Tu, Yen-Cheng Aziz, Izzat Budiman, Arief S. Tan, Cher Ming Lee, Pooi See Thomas, Olivier Raghavan, Nagarajan Investigation of the reliability of nano-nickel/niobium oxide-based multilayer thin films deposited on polymer substrates for flexible electronic applications |
| description |
Flexible electronics are attractive for a range of applications, such as wearable gadgets and personalized medicine, because of their flexibility, stretchability, and adaptability. However, the reliability of such devices, both mechanical and electrical, is a bottleneck for their widespread application across different use-case scenarios. Here, we report the reliability of nickel-niobium oxide (crystalline-amorphous) sandwich nanolayers on a PI substrate (Ni-Nb2O5-PI) compared to pure nickel (Ni) nanolayers on a PI substrate (Ni-PI) as a potential candidate for electrodes or interconnects for flexible electronic or energy devices. A tailored rate-dependent bending failure/fracture test system was used to analyze the electrical resistance (oscillations) as a function of the loading cycles of the sample deposited on polyimide (PI) (the compliant substrate). Resistance oscillation amplitude during the rate-dependent bending failure/fracture test for Ni-PI (∼6%) was higher compared to that of Ni-Nb2O5-PI (∼2%), suggesting a low resistance change and consequently low mechanical deformation for Ni-Nb2O5-PI. Nanoindentation experiments were also performed to ascertain the hardness and reduced elastic modulus of the samples. Hardness of Ni-PI (∼1.4 GPa) was lower compared to that of Ni-Nb2O5-PI (∼2.4 GPa) suggesting high flow strength for Ni-Nb2O5-PI. Therefore, the incorporation of amorphous niobium oxide into samples otherwise composed of Ni nanolayers significantly improved their fatigue/fracture strength with a slight reduction in electrical conductivity with appreciably low resistance oscillation (amplitude) essential for operational reliability of flexible devices. We also demonstrated that the nickel-niobium oxide/polyimide stack was electrically/mechanically stable up to 500 K stress cycles at a bending radius of 8.5 mm. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Sahay, Rahul Tu, Yen-Cheng Aziz, Izzat Budiman, Arief S. Tan, Cher Ming Lee, Pooi See Thomas, Olivier Raghavan, Nagarajan |
| format |
Article |
| author |
Sahay, Rahul Tu, Yen-Cheng Aziz, Izzat Budiman, Arief S. Tan, Cher Ming Lee, Pooi See Thomas, Olivier Raghavan, Nagarajan |
| author_sort |
Sahay, Rahul |
| title |
Investigation of the reliability of nano-nickel/niobium oxide-based multilayer thin films deposited on polymer substrates for flexible electronic applications |
| title_short |
Investigation of the reliability of nano-nickel/niobium oxide-based multilayer thin films deposited on polymer substrates for flexible electronic applications |
| title_full |
Investigation of the reliability of nano-nickel/niobium oxide-based multilayer thin films deposited on polymer substrates for flexible electronic applications |
| title_fullStr |
Investigation of the reliability of nano-nickel/niobium oxide-based multilayer thin films deposited on polymer substrates for flexible electronic applications |
| title_full_unstemmed |
Investigation of the reliability of nano-nickel/niobium oxide-based multilayer thin films deposited on polymer substrates for flexible electronic applications |
| title_sort |
investigation of the reliability of nano-nickel/niobium oxide-based multilayer thin films deposited on polymer substrates for flexible electronic applications |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/173547 |
| _version_ |
1794549472755187712 |