Standard

Broadband efficient light-absorbing SS-PPy@CNT membranes prepared by electrochemical deposition for photothermal conversion. / Liu, Mengyan; Zhu, Benfeng; Chen, Na; Zhu, Jie; Lei, Caihe; Li, Ruopeng; Yang, Yumeng; Liu, Jiao; Zhang, Zhao; Yang, Peixia; Levin, Oleg; Alekseeva, Elena; Fang, Bo; Wei, Guoying; Yang, Jingjing.

в: Renewable Energy, Том 237, № Part D, 121926, 01.12.2024.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

Liu, M, Zhu, B, Chen, N, Zhu, J, Lei, C, Li, R, Yang, Y, Liu, J, Zhang, Z, Yang, P, Levin, O, Alekseeva, E, Fang, B, Wei, G & Yang, J 2024, 'Broadband efficient light-absorbing SS-PPy@CNT membranes prepared by electrochemical deposition for photothermal conversion', Renewable Energy, Том. 237, № Part D, 121926. https://doi.org/10.1016/j.renene.2024.121926

APA

Liu, M., Zhu, B., Chen, N., Zhu, J., Lei, C., Li, R., Yang, Y., Liu, J., Zhang, Z., Yang, P., Levin, O., Alekseeva, E., Fang, B., Wei, G., & Yang, J. (2024). Broadband efficient light-absorbing SS-PPy@CNT membranes prepared by electrochemical deposition for photothermal conversion. Renewable Energy, 237(Part D), [121926]. https://doi.org/10.1016/j.renene.2024.121926

Vancouver

Author

Liu, Mengyan ; Zhu, Benfeng ; Chen, Na ; Zhu, Jie ; Lei, Caihe ; Li, Ruopeng ; Yang, Yumeng ; Liu, Jiao ; Zhang, Zhao ; Yang, Peixia ; Levin, Oleg ; Alekseeva, Elena ; Fang, Bo ; Wei, Guoying ; Yang, Jingjing. / Broadband efficient light-absorbing SS-PPy@CNT membranes prepared by electrochemical deposition for photothermal conversion. в: Renewable Energy. 2024 ; Том 237, № Part D.

BibTeX

@article{981b309eeb1d46aebbb14181637292eb,
title = "Broadband efficient light-absorbing SS-PPy@CNT membranes prepared by electrochemical deposition for photothermal conversion",
abstract = "Solar energy is an eco-conscious substitute, for solar energy absorption and subsequent light-to-heat conversion, light-absorbing materials require broad-spectrum light absorption capabilities. Herein, we present the fabrication of broadband light-absorbing polypyrrole-carboxylated carbon nanotube membranes via a facile electrochemical deposition route. By manipulating electrochemical deposition time, the structure of the membranes was tailored, resulting in enhanced absorption, achieving over 98.95 % across the entire solar spectrum. The membranes demonstrated exemplary thermal efficacy and insensitivity to incident angles in photothermal conversion, the membranes facilitated a notable 12 °C temperature elevation within a simulated greenhouse compared to ambient conditions. Thus, these membranes exhibit considerable potential for widespread application in photothermal conversion and greenhouse technology.",
keywords = "Broadband light absorption, Carbon nanotubes, Electrochemical deposition, Micro-nano structure, Photothermal conversion",
author = "Mengyan Liu and Benfeng Zhu and Na Chen and Jie Zhu and Caihe Lei and Ruopeng Li and Yumeng Yang and Jiao Liu and Zhao Zhang and Peixia Yang and Oleg Levin and Elena Alekseeva and Bo Fang and Guoying Wei and Jingjing Yang",
year = "2024",
month = dec,
day = "1",
doi = "10.1016/j.renene.2024.121926",
language = "English",
volume = "237",
journal = "Renewable Energy",
issn = "0960-1481",
publisher = "Elsevier",
number = "Part D",

}

RIS

TY - JOUR

T1 - Broadband efficient light-absorbing SS-PPy@CNT membranes prepared by electrochemical deposition for photothermal conversion

AU - Liu, Mengyan

AU - Zhu, Benfeng

AU - Chen, Na

AU - Zhu, Jie

AU - Lei, Caihe

AU - Li, Ruopeng

AU - Yang, Yumeng

AU - Liu, Jiao

AU - Zhang, Zhao

AU - Yang, Peixia

AU - Levin, Oleg

AU - Alekseeva, Elena

AU - Fang, Bo

AU - Wei, Guoying

AU - Yang, Jingjing

PY - 2024/12/1

Y1 - 2024/12/1

N2 - Solar energy is an eco-conscious substitute, for solar energy absorption and subsequent light-to-heat conversion, light-absorbing materials require broad-spectrum light absorption capabilities. Herein, we present the fabrication of broadband light-absorbing polypyrrole-carboxylated carbon nanotube membranes via a facile electrochemical deposition route. By manipulating electrochemical deposition time, the structure of the membranes was tailored, resulting in enhanced absorption, achieving over 98.95 % across the entire solar spectrum. The membranes demonstrated exemplary thermal efficacy and insensitivity to incident angles in photothermal conversion, the membranes facilitated a notable 12 °C temperature elevation within a simulated greenhouse compared to ambient conditions. Thus, these membranes exhibit considerable potential for widespread application in photothermal conversion and greenhouse technology.

AB - Solar energy is an eco-conscious substitute, for solar energy absorption and subsequent light-to-heat conversion, light-absorbing materials require broad-spectrum light absorption capabilities. Herein, we present the fabrication of broadband light-absorbing polypyrrole-carboxylated carbon nanotube membranes via a facile electrochemical deposition route. By manipulating electrochemical deposition time, the structure of the membranes was tailored, resulting in enhanced absorption, achieving over 98.95 % across the entire solar spectrum. The membranes demonstrated exemplary thermal efficacy and insensitivity to incident angles in photothermal conversion, the membranes facilitated a notable 12 °C temperature elevation within a simulated greenhouse compared to ambient conditions. Thus, these membranes exhibit considerable potential for widespread application in photothermal conversion and greenhouse technology.

KW - Broadband light absorption

KW - Carbon nanotubes

KW - Electrochemical deposition

KW - Micro-nano structure

KW - Photothermal conversion

UR - https://www.mendeley.com/catalogue/909b4e35-01d7-3082-a813-45b371e29fd9/

U2 - 10.1016/j.renene.2024.121926

DO - 10.1016/j.renene.2024.121926

M3 - Article

VL - 237

JO - Renewable Energy

JF - Renewable Energy

SN - 0960-1481

IS - Part D

M1 - 121926

ER -

ID: 127278989