Flexible electronics has emerged as a promising field for the development of electronic devices with applications in wearables, biomedical sensors, and edible electronics. Biomaterials play a crucial role in fabricating flexible substrates, and the utilization of polymer blends offers exciting possibilities for tuning mechanical and chemical properties. This paper highlights the potential of a novel polymer blend based on ethyl cellulose (EC) and hydroxypropyl cellulose (HPC) in the fabrication of substrates for flexible electronics. By blending the two cellulose ethers, it is possible to tune the mechanical and chemical properties of the final substrate, tailored to meet specific requirements. To exploit such innovative green substrates for photolithographic processes, their stability, and processability is extensively investigated. The feasibility of photolithographic processes on such biodegradable and edible substrates is demonstrated by fabricating both resistive and capacitive sensors through standard photolithographic processes, presenting a breakthrough in terms of applicability. The utilization of such biomaterials holds tremendous potential for driving technological advancements in various fields. These materials pave the way for innovative devices catering to diverse applications, from agriculture to food and biomedicine. Importantly, they also promote a sustainable approach for their fabrication, laying the foundation for an environment-aware future of technological progress.

Palmieri, E., Maiolo, L., Lucarini, I., DIAZ FATTORINI, A., Tamburri, E., Orlanducci, S., et al. (2024). Toward sustainable electronics: exploiting the potential of a biodegradable cellulose blend for photolithographic processes and eco‐friendly devices. ADVANCED MATERIALS TECHNOLOGIES, 9(1) [10.1002/admt.202301282].

Toward sustainable electronics: exploiting the potential of a biodegradable cellulose blend for photolithographic processes and eco‐friendly devices

Elena Palmieri;Adriano Diaz Fattorini;Emanuela Tamburri;Silvia Orlanducci;
2024-01-01

Abstract

Flexible electronics has emerged as a promising field for the development of electronic devices with applications in wearables, biomedical sensors, and edible electronics. Biomaterials play a crucial role in fabricating flexible substrates, and the utilization of polymer blends offers exciting possibilities for tuning mechanical and chemical properties. This paper highlights the potential of a novel polymer blend based on ethyl cellulose (EC) and hydroxypropyl cellulose (HPC) in the fabrication of substrates for flexible electronics. By blending the two cellulose ethers, it is possible to tune the mechanical and chemical properties of the final substrate, tailored to meet specific requirements. To exploit such innovative green substrates for photolithographic processes, their stability, and processability is extensively investigated. The feasibility of photolithographic processes on such biodegradable and edible substrates is demonstrated by fabricating both resistive and capacitive sensors through standard photolithographic processes, presenting a breakthrough in terms of applicability. The utilization of such biomaterials holds tremendous potential for driving technological advancements in various fields. These materials pave the way for innovative devices catering to diverse applications, from agriculture to food and biomedicine. Importantly, they also promote a sustainable approach for their fabrication, laying the foundation for an environment-aware future of technological progress.
2024
Pubblicato
Rilevanza internazionale
Articolo
Esperti anonimi
Settore CHIM/03
English
Con Impact Factor ISI
sustainable electronics; biodegradable cellulose; photolithographic processes
Palmieri, E., Maiolo, L., Lucarini, I., DIAZ FATTORINI, A., Tamburri, E., Orlanducci, S., et al. (2024). Toward sustainable electronics: exploiting the potential of a biodegradable cellulose blend for photolithographic processes and eco‐friendly devices. ADVANCED MATERIALS TECHNOLOGIES, 9(1) [10.1002/admt.202301282].
Palmieri, E; Maiolo, L; Lucarini, I; DIAZ FATTORINI, A; Tamburri, E; Orlanducci, S; Calarco, R; Maita, F
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2108/345525
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