Ultrafast hydrothermal assembly of nanocarbon microfibers in near-critical water for 3D microsupercapacitors
Translating the advantages of carbon nanomaterials into macroscopic energy storage devices is challenging because the desirable nanoscale properties often disappear during assembly processes. Here we describe a new nonequilibrium subcritical hydrothermal method capable of independently manipulating...
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sg-ntu-dr.10356-1389662020-05-14T06:28:15Z Ultrafast hydrothermal assembly of nanocarbon microfibers in near-critical water for 3D microsupercapacitors Zhai, Shengli Wei, Li. Karahan, Huseyin Enis Wang, Yanqing Wang, Chaojun Montoya, Alejandro Shao, Qian Wang, Xin Chen, Yue School of Chemical and Biomedical Engineering Engineering::Chemical engineering Capacitance Energy Conservation Translating the advantages of carbon nanomaterials into macroscopic energy storage devices is challenging because the desirable nanoscale properties often disappear during assembly processes. Here we describe a new nonequilibrium subcritical hydrothermal method capable of independently manipulating the temperature and pressure to create unique assembly conditions crossing the commonly used liquid-vapor boundary. Highly conductive and dense-packed yet ion-accessible nanocarbon microfibers can be obtained from graphene oxide sheets, single-walled carbon nanotubes, and a nitrogen-doping crosslinker under 20 min of hydrothermal assembly, 80% energy saving compared to standard hydrothermal methods, and one of the shortest time in the field of hydrothermal processing of carbon nanomaterials. Using those microfibers, we built microsupercapacitors that reach a high volumetric capacitance of 52 F cm−3, energy density of 7.1 mWh cm−3, and power density of 1645.7 mW cm−3, respectively. We further demonstrate the 3D integration of multiple fiber microsupercapacitors that reduces the device footprint by 75% while expanding the operational voltage and current window. This strategy is a promising tool for harmoniously assembling carbon nanostructures as energy storage components for various energy applications. 2020-05-14T06:28:15Z 2020-05-14T06:28:15Z 2018 Journal Article Zhai, S., Wei, L., Karahan, H. E., Wang, Y., Wang, C., Montoya, A., . . . Chen, Y. (2018). Ultrafast hydrothermal assembly of nanocarbon microfibers in near-critical water for 3D microsupercapacitors. Carbon, 132, 698-708. doi:10.1016/j.carbon.2018.02.089 0008-6223 https://hdl.handle.net/10356/138966 10.1016/j.carbon.2018.02.089 2-s2.0-85043310620 132 698 708 en Carbon © 2018 Elsevier Ltd. All rights reserved |
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Engineering::Chemical engineering Capacitance Energy Conservation Zhai, Shengli Wei, Li. Karahan, Huseyin Enis Wang, Yanqing Wang, Chaojun Montoya, Alejandro Shao, Qian Wang, Xin Chen, Yue Ultrafast hydrothermal assembly of nanocarbon microfibers in near-critical water for 3D microsupercapacitors |
| description |
Translating the advantages of carbon nanomaterials into macroscopic energy storage devices is challenging because the desirable nanoscale properties often disappear during assembly processes. Here we describe a new nonequilibrium subcritical hydrothermal method capable of independently manipulating the temperature and pressure to create unique assembly conditions crossing the commonly used liquid-vapor boundary. Highly conductive and dense-packed yet ion-accessible nanocarbon microfibers can be obtained from graphene oxide sheets, single-walled carbon nanotubes, and a nitrogen-doping crosslinker under 20 min of hydrothermal assembly, 80% energy saving compared to standard hydrothermal methods, and one of the shortest time in the field of hydrothermal processing of carbon nanomaterials. Using those microfibers, we built microsupercapacitors that reach a high volumetric capacitance of 52 F cm−3, energy density of 7.1 mWh cm−3, and power density of 1645.7 mW cm−3, respectively. We further demonstrate the 3D integration of multiple fiber microsupercapacitors that reduces the device footprint by 75% while expanding the operational voltage and current window. This strategy is a promising tool for harmoniously assembling carbon nanostructures as energy storage components for various energy applications. |
| author2 |
School of Chemical and Biomedical Engineering |
| author_facet |
School of Chemical and Biomedical Engineering Zhai, Shengli Wei, Li. Karahan, Huseyin Enis Wang, Yanqing Wang, Chaojun Montoya, Alejandro Shao, Qian Wang, Xin Chen, Yue |
| format |
Article |
| author |
Zhai, Shengli Wei, Li. Karahan, Huseyin Enis Wang, Yanqing Wang, Chaojun Montoya, Alejandro Shao, Qian Wang, Xin Chen, Yue |
| author_sort |
Zhai, Shengli |
| title |
Ultrafast hydrothermal assembly of nanocarbon microfibers in near-critical water for 3D microsupercapacitors |
| title_short |
Ultrafast hydrothermal assembly of nanocarbon microfibers in near-critical water for 3D microsupercapacitors |
| title_full |
Ultrafast hydrothermal assembly of nanocarbon microfibers in near-critical water for 3D microsupercapacitors |
| title_fullStr |
Ultrafast hydrothermal assembly of nanocarbon microfibers in near-critical water for 3D microsupercapacitors |
| title_full_unstemmed |
Ultrafast hydrothermal assembly of nanocarbon microfibers in near-critical water for 3D microsupercapacitors |
| title_sort |
ultrafast hydrothermal assembly of nanocarbon microfibers in near-critical water for 3d microsupercapacitors |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/138966 |
| _version_ |
1681056749933559808 |