Anthony Camus, Shinhyeong Choe, Camille Bour-Cardinal, Joaquin Isasmendi, Yong-Jun Cho, Youngju Kim, Cristian Vlad Irimia, Cigdem Yumusak, Mihai Irimia‐Vladu, Jaewook Myung and Clara Santato
Article (2024)
Open Acess document in PolyPublie and at official publisher |
|
Open Access to the full text of this document Published Version Terms of Use: Creative Commons Attribution Non-commercial No Derivatives Download (3MB) |
|
|
Open Access to the full text of this document Supplemental Material Terms of Use: Creative Commons Attribution Non-commercial No Derivatives Download (2MB) |
Abstract
Sepia melanin, a biopigment extracted from the ink sac of cuttlefish, is relevant to sustainable organic electronics. In this work, we flexographically print films from an ink of Sepia melanin including shellac as a bio-sourced binder on silver electrode-patterned paper. We examine the electrical response in high humidity and ambient conditions (here the electronic conductivity is as high as 10−4 S/cm). Additionally, we study the biodegradation of the printed films and their individual constituents based on their mineralization into CO2 under composting conditions. The printed films exhibit biodegradation levels of about 97 ± 25% in 85 d. We observe microorganism colonization on the printed film’s surface. The analysis of the microbial community on the compost reveals that bacterial species within the Acidimicrobiia class, specifically Actinomarinales order, are potentially responsible for the biodegradation of the printed film. Meanwhile, ecotoxicity tests conducted by germinating Lolium multiflorum and Tagetes erecta suggest that printed films have negligible phytotoxicity.
Uncontrolled Keywords
electronic devices; environmental impact
Subjects: | 3100 Physics > 3100 Physics |
---|---|
Department: | Department of Engineering Physics |
Funders: | National Research Foundation of Korea (NRF), KAIST Venture Research Program for Master’s and Ph.D. Students, KAIST Creative & Challenging (C2) Program, Hyundai Motor Chung Mong-Koo Foundation, Project “EINSTEIN”, NSER / GRSNG, Canada Research Chair in Sustainable Organic Electronics |
Grant number: | 2022R1A4A3029607, 2023K2A9A1A01098411, RS-2023-00209472, RGPIN-2022-04640, 950-232719 |
PolyPublie URL: | https://publications.polymtl.ca/59185/ |
Journal Title: | Communications Materials (vol. 5) |
Publisher: | Nature Portfolio |
DOI: | 10.1038/s43246-024-00592-3 |
Official URL: | https://doi.org/10.1038/s43246-024-00592-3 |
Date Deposited: | 18 Sep 2024 14:46 |
Last Modified: | 04 Dec 2024 01:48 |
Cite in APA 7: | Camus, A., Choe, S., Bour-Cardinal, C., Isasmendi, J., Cho, Y.-J., Kim, Y., Irimia, C. V., Yumusak, C., Irimia‐Vladu, M., Myung, J., & Santato, C. (2024). Electrical response and biodegradation of Sepia melanin-shellac films printed on paper. Communications Materials, 5, 173 (13 pages). https://doi.org/10.1038/s43246-024-00592-3 |
---|---|
Statistics
Total downloads
Downloads per month in the last year
Origin of downloads
Dimensions