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Nanocellulose-based flexible electrodes for safe and sustainable energy storage

Nanocellulose-based flexible electrodes for safe and sustainable energy storage
Nanocellulose-based flexible electrodes for safe and sustainable energy storage
The intensive use of battery-powered electronic devices, in addition to the challenging recycling requirements, have contributed to the accumulation of e-waste, one of the most alarming environmental issues of the modern world. This urges the importance of developing advanced energy storage systems by using non-toxic and more sustainable materials1. Nanocellulose as the most abundant bio-polymer, can tackle current ecological and safety concerns but also keep up with contemporary resilience requisites in powering flexible electronics. Herein, we present the development of organic nanocellulose-based battery electrodes, that can be used in applications with relatively low energy storage demands, such as medical systems, wearables and bendable Internet of Things (IoT) devices. We investigate hybrid electrodes composed of nanocellulose fibres and carbon-based battery active materials, by implementing a safer, aqueous fabrication processing and with a focus on understanding the underlying charge storage mechanisms2. The main constituent of the electrodes is a porous nanocellulose network that maintains structural integrity acting as a binder but also transports ions from an organic electrolyte to the active battery material with reduced diffusion limitations. The overall battery structure is flexible and mechanically robust, minimizing any volume changes during charge/discharge, which translates to cycling stability3.

The nanocellulose-based electrodes were manufactured by using different techniques including vacuum filtration and blade coating, and yielded free-standing and current-collector-integrated electrodes. Structural properties and surface morphology were examined via atomic force microscopy (tapping mode and conductive-AFM), and scanning electron microscopy with energy dispersive X-ray spectroscopy (SEM-EDX), while electrochemical atomic force microscopy (EC-AFM) was used for in operando visualization and elucidation of molecular level charge transfer mechanisms occurring at the electrode-electrolyte interface. Electrochemical performance was assessed by variable-rate cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS) and chronopotentiometry (CP). Furthermore, bending stress tests were conducted where the bending radius and charge/discharge profile of the electrode are correlated. The proposed battery concept paves the way for safe, non-toxic, mechanically flexible and sustainable energy storage technologies that aim to fulfil the growing need for low-power commercial devices.

References

Leung, O. M., Schoetz, T., Prodromakis, T. & Ponce de Leon, C. Review—Progress in Electrolytes for Rechargeable Aluminium Batteries. Journal of The Electrochemical Society 168, 056509 (2021).

Schoetz, T., Gordon, L., Ivanov, S., Bund, A., Mandler, D. & Messinger, R. Disentangling faradaic, pseudocapacitive, and capacitive charge storage: A tutorial for the characterization of batteries, supercapacitors, and hybrid systems. Electrochimica Acta 412, 140072 (2022).

Kim, J.-H., Lee, D., Lee, Y.-H., Chen, W. & Lee, S.-Y. Nanocellulose for Energy Storage Systems: Beyond the Limits of Synthetic Materials. Advanced Materials 31, 1804826 (2019).
The Electrochemical Society
Founta, Evangelia
f95ed818-0469-45c3-a838-03ace6fa6ed8
Schoetz, Theresa
6a75dac5-ee39-401f-896f-cdc7ff76e0f6
Georgiadou, Dimitra
84977176-3678-4fb3-a3dd-2044a49c853b
Prodromakis, Themis
d58c9c10-9d25-4d22-b155-06c8437acfbf
Ponce De Leon Albarran, Carlos
508a312e-75ff-4bcb-9151-dacc424d755c
Founta, Evangelia
f95ed818-0469-45c3-a838-03ace6fa6ed8
Schoetz, Theresa
6a75dac5-ee39-401f-896f-cdc7ff76e0f6
Georgiadou, Dimitra
84977176-3678-4fb3-a3dd-2044a49c853b
Prodromakis, Themis
d58c9c10-9d25-4d22-b155-06c8437acfbf
Ponce De Leon Albarran, Carlos
508a312e-75ff-4bcb-9151-dacc424d755c

Founta, Evangelia, Schoetz, Theresa, Georgiadou, Dimitra, Prodromakis, Themis and Ponce De Leon Albarran, Carlos (2022) Nanocellulose-based flexible electrodes for safe and sustainable energy storage. In ECS Meeting Abstracts. vol. MA2022-02, The Electrochemical Society.. (doi:10.1149/MA2022-023275mtgabs).

Record type: Conference or Workshop Item (Paper)

Abstract

The intensive use of battery-powered electronic devices, in addition to the challenging recycling requirements, have contributed to the accumulation of e-waste, one of the most alarming environmental issues of the modern world. This urges the importance of developing advanced energy storage systems by using non-toxic and more sustainable materials1. Nanocellulose as the most abundant bio-polymer, can tackle current ecological and safety concerns but also keep up with contemporary resilience requisites in powering flexible electronics. Herein, we present the development of organic nanocellulose-based battery electrodes, that can be used in applications with relatively low energy storage demands, such as medical systems, wearables and bendable Internet of Things (IoT) devices. We investigate hybrid electrodes composed of nanocellulose fibres and carbon-based battery active materials, by implementing a safer, aqueous fabrication processing and with a focus on understanding the underlying charge storage mechanisms2. The main constituent of the electrodes is a porous nanocellulose network that maintains structural integrity acting as a binder but also transports ions from an organic electrolyte to the active battery material with reduced diffusion limitations. The overall battery structure is flexible and mechanically robust, minimizing any volume changes during charge/discharge, which translates to cycling stability3.

The nanocellulose-based electrodes were manufactured by using different techniques including vacuum filtration and blade coating, and yielded free-standing and current-collector-integrated electrodes. Structural properties and surface morphology were examined via atomic force microscopy (tapping mode and conductive-AFM), and scanning electron microscopy with energy dispersive X-ray spectroscopy (SEM-EDX), while electrochemical atomic force microscopy (EC-AFM) was used for in operando visualization and elucidation of molecular level charge transfer mechanisms occurring at the electrode-electrolyte interface. Electrochemical performance was assessed by variable-rate cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS) and chronopotentiometry (CP). Furthermore, bending stress tests were conducted where the bending radius and charge/discharge profile of the electrode are correlated. The proposed battery concept paves the way for safe, non-toxic, mechanically flexible and sustainable energy storage technologies that aim to fulfil the growing need for low-power commercial devices.

References

Leung, O. M., Schoetz, T., Prodromakis, T. & Ponce de Leon, C. Review—Progress in Electrolytes for Rechargeable Aluminium Batteries. Journal of The Electrochemical Society 168, 056509 (2021).

Schoetz, T., Gordon, L., Ivanov, S., Bund, A., Mandler, D. & Messinger, R. Disentangling faradaic, pseudocapacitive, and capacitive charge storage: A tutorial for the characterization of batteries, supercapacitors, and hybrid systems. Electrochimica Acta 412, 140072 (2022).

Kim, J.-H., Lee, D., Lee, Y.-H., Chen, W. & Lee, S.-Y. Nanocellulose for Energy Storage Systems: Beyond the Limits of Synthetic Materials. Advanced Materials 31, 1804826 (2019).

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Published date: 2022

Identifiers

Local EPrints ID: 473442
URI: http://eprints.soton.ac.uk/id/eprint/473442
PURE UUID: 5070b63e-967e-4937-9e7b-4a5393af2775
ORCID for Evangelia Founta: ORCID iD orcid.org/0000-0001-6459-8417
ORCID for Dimitra Georgiadou: ORCID iD orcid.org/0000-0002-2620-3346
ORCID for Themis Prodromakis: ORCID iD orcid.org/0000-0002-6267-6909
ORCID for Carlos Ponce De Leon Albarran: ORCID iD orcid.org/0000-0002-1907-5913

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Date deposited: 18 Jan 2023 17:44
Last modified: 17 Mar 2024 04:03

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Author: Evangelia Founta ORCID iD
Author: Theresa Schoetz
Author: Themis Prodromakis ORCID iD

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