All carbon based high energy lithium-ion capacitors from biomass : the role of crystallinity
We report all carbon-based high energy Li-ion capacitor from environmentally threatening bio-source, prosopis juliflora. The pyrolyzed carbon exhibits a few layers of graphene-like structure and tubular morphology with multiple inherent heteroatoms like N, S, and Ca. Presence of such heteroatoms are...
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sg-ntu-dr.10356-1470462021-03-19T03:05:20Z All carbon based high energy lithium-ion capacitors from biomass : the role of crystallinity Sennu, Palanichamy Arun, Nagasubramanian Madhavi, Srinivasan Aravindan, Vanchiappan Lee, Yun-Sung School of Materials Science and Engineering Engineering::Materials Lithium-ion Capacitor Few-layer Graphene We report all carbon-based high energy Li-ion capacitor from environmentally threatening bio-source, prosopis juliflora. The pyrolyzed carbon exhibits a few layers of graphene-like structure and tubular morphology with multiple inherent heteroatoms like N, S, and Ca. Presence of such heteroatoms are certainly beneficial to the betterment of electrical conductivity, and pore generation which eventually results in an enhancement in capacity/capacitance of carbonaceous materials. The electrochemical pre-lithiation strategy is used to mitigate the irreversibility observed, and eventually employed as a negative electrode in a hybrid configuration. This LIC delivered a high energy density of ∼216 and 185 Wh kg−1 at ambient (25 °C) and elevated temperature (55 °C) conditions, respectively. Further, ∼94% initial capacity is retained after 5000 cycles with minimum fading of 0.0013% per cycle at ambient temperature. This results clearly demonstrate that the surface functionality and heteroatom doping with tubular structure synergistically facilitates the Li+ and electron transport properties to realize higher energy density for this fascinating all carbon-based Li-ion capacitor. National Research Foundation (NRF) This study was supported by the National Research Foundation of Korea grant funded by the Korea government (Ministry of Science, ICT) (No. NRF-2011-C1AAA0010030538). Also, the work was financially supported by NTU-HUJ Create Phase II which is a joint research programme between the Hebrew University of Jerusalem (HUJ, Israel) and Nanyang Technological University (NTU, Singapore) with CREATE (Campus for Research Excellence and Technological Enterprise) funding from National Research Foundation of Singapore (NRF,Singapore). VA thank the financial support from the Science & Engineering Research Board (SERB), a statutory body of the Department of Science & Technology, Govt. of India through Ramanujan Fellowship (SB/S2/RJN-088/2016). 2021-03-19T01:51:57Z 2021-03-19T01:51:57Z 2019 Journal Article Sennu, P., Arun, N., Madhavi, S., Aravindan, V. & Lee, Y. (2019). All carbon based high energy lithium-ion capacitors from biomass : the role of crystallinity. Journal of Power Sources, 414, 96-102. https://dx.doi.org/10.1016/j.jpowsour.2018.12.089 0378-7753 https://hdl.handle.net/10356/147046 10.1016/j.jpowsour.2018.12.089 2-s2.0-85059451525 414 96 102 en NRF-2011-C1AAA0010030538 Journal of Power Sources © 2019 Elsevier B.V. All rights reserved. |
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Engineering::Materials Lithium-ion Capacitor Few-layer Graphene |
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Engineering::Materials Lithium-ion Capacitor Few-layer Graphene Sennu, Palanichamy Arun, Nagasubramanian Madhavi, Srinivasan Aravindan, Vanchiappan Lee, Yun-Sung All carbon based high energy lithium-ion capacitors from biomass : the role of crystallinity |
| description |
We report all carbon-based high energy Li-ion capacitor from environmentally threatening bio-source, prosopis juliflora. The pyrolyzed carbon exhibits a few layers of graphene-like structure and tubular morphology with multiple inherent heteroatoms like N, S, and Ca. Presence of such heteroatoms are certainly beneficial to the betterment of electrical conductivity, and pore generation which eventually results in an enhancement in capacity/capacitance of carbonaceous materials. The electrochemical pre-lithiation strategy is used to mitigate the irreversibility observed, and eventually employed as a negative electrode in a hybrid configuration. This LIC delivered a high energy density of ∼216 and 185 Wh kg−1 at ambient (25 °C) and elevated temperature (55 °C) conditions, respectively. Further, ∼94% initial capacity is retained after 5000 cycles with minimum fading of 0.0013% per cycle at ambient temperature. This results clearly demonstrate that the surface functionality and heteroatom doping with tubular structure synergistically facilitates the Li+ and electron transport properties to realize higher energy density for this fascinating all carbon-based Li-ion capacitor. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Sennu, Palanichamy Arun, Nagasubramanian Madhavi, Srinivasan Aravindan, Vanchiappan Lee, Yun-Sung |
| format |
Article |
| author |
Sennu, Palanichamy Arun, Nagasubramanian Madhavi, Srinivasan Aravindan, Vanchiappan Lee, Yun-Sung |
| author_sort |
Sennu, Palanichamy |
| title |
All carbon based high energy lithium-ion capacitors from biomass : the role of crystallinity |
| title_short |
All carbon based high energy lithium-ion capacitors from biomass : the role of crystallinity |
| title_full |
All carbon based high energy lithium-ion capacitors from biomass : the role of crystallinity |
| title_fullStr |
All carbon based high energy lithium-ion capacitors from biomass : the role of crystallinity |
| title_full_unstemmed |
All carbon based high energy lithium-ion capacitors from biomass : the role of crystallinity |
| title_sort |
all carbon based high energy lithium-ion capacitors from biomass : the role of crystallinity |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/147046 |
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1696984385295745024 |