Published September 20, 2024 | Version v1
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Surface Optimisation of Regenerated Cellulose Membranes for development of a sustainable and efficient low-grade waste heat harvester

Description

ABSTRACT:

Around 70% of global energy generated is lost as waste heat.  Hence an efficient and sustainable technology is required to convert low-grade heat (≤ 100 °C) into a useful form of energy. Conventional technology does not allow efficient conversion of low-grade heat into useful forms of energy, such as electricity. The selective movement of ions in nanoscale channels, driven by a temperature gradient (ΔT), can be utilised to generate electricity from low grade waste heat1.  This presentation describes surface functionalised, sustainable, and biocompatible regenerated cellulose membranes as components for ionic thermoelectric energy harvesters, capable of generating electricity under a moderate temperature gradient. Membranes were functionalised with appropriate organic moieties, such as negatively charged TEMPO (2,2,6,6-tetramethylpiperidin-1-oxyl) and positively charged CHMAC (3-chloro-2-hydroxypropyl)trimethylammonium chloride), to enhance their pore wall charge densities and maximise their ability to convert thermal energy into electrical energy. Successful functionalisation of the membrane channels is confirmed by infrared spectroscopy, contact angle measurements and scanning electron microscopy, as well as various electrochemical characterisation techniques such as linear sweep voltammetry (LSV). Functionalization enhanced the charge density of TEMPO cellulose by over 11 times, resulting in a 250-fold increase in ionic conductivity. With CHMAC functionalisation, the ionic conductivity increased around 600 times than that of the pristine. These functionalised and electrolyte-filled membranes are being investigated for ionic thermoelectrics. A thermovoltage of -3.68 mV K-1 was achieved with CHMAC functionalised cellulose membranes.  


Reference
1.    Li, T., Zhang, X., Lacey, S.D. et al. Cellulose ionic conductors with high differential thermal voltage for low-grade heat harvesting. Nat. Mater. 18, 608–613 (2019). https://doi.org/10.1038/s41563-019-0315-6

Notes (English)

TRANSLATE is a €3.4 million EU-funded research project that aims to develop a new nanofluidic platform technology to effectively convert waste heat to electricity. This technology has the potential to improve the energy efficiency of many devices and systems, and provide a radically new zero-emission power source. The TRANSLATE project has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement number 964251, for the action of 'The Recycling of waste heat through the Application of Nanofluidic ChannelS: Advances in the Conversion of Thermal to Electrical energy'. More information can be be found on the TRANSLATE project website: https://translate-energy.eu/

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Additional details

Funding

European Commission
TRANSLATE – The Recycling of waste heat through the Application of Nanofluidic ChannelS: Advances in the Conversion of Thermal to Electrical energy 964251

Dates

Available
2024-09-20