Journal
INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER
Volume 200, Issue -, Pages -Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.ijheatmasstransfer.2022.123509
Keywords
Energy harvesting; Conical nanopore; salinity gradient; Temperature gradient; Energy device
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This paper proposes an energy harvesting system based on charged conical nanopore and investigates the influence of salinity and temperature gradient on the maximum output power and energy conversion efficiency. The results show that the enhancement of negative temperature difference has a more significant effect on the maximum output power, and the system achieves a maximum optimal value of 0.22 pW.
Renewable energy has been received more attention with the increasingly serious energy crisis. In this paper, an energy harvesting system from charged conical nanopore with coupled salinity and tempera-ture gradient is proposed. The results show that the obtained maximum power increases first and then decreases as the concentration difference increases. Particularly, the enhancement of negative tempera-ture difference (NTD) on maximum output power and the corresponding energy conversion efficiency is more significant compared with positive temperature difference (PTD) due to the simultaneous increase of short circuit current and open circuit voltage. Besides, the maximum output power is larger when the low concentration reservoir is connected to the tip end of the conical nanopore. The obtained maximum optimal value is about 0.22 pW. In the further investigation of a temperature gradient, we found that the short circuit current, open circuit voltage, and maximum output power show the approximately linear thermal response characteristics as the temperature difference is increased. Besides, an interesting com-petive mechanism between the concentration gradient effect and temperature gradient effect is found, which determines the prior conical nanopore orientation. The related research results provide useful in-formation for the design and optimization of energy devices.(c) 2022 Elsevier Ltd. All rights reserved.
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