Polarity-induced precipitation of S/Li2S confined into N and S co-doped porous graphene layered matrix for lithium sulfur batteries

Polarity-induced precipitation of S/Li2S confined into N and S co-doped porous graphene layered matrix for lithium sulfur batteries

The large-scale application of lithium sulfur batteries is impeded by their cycling stability and power performance mainly due to the polysulfide shuttle effect and low conductivity of sulfur. Herein, a multifunctional sulfur host of N/S co-doped porous graphene layered matrix (NSPG) is fabricated....

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Veröffentlicht in:Carbon (New York) 2021-10, Vol.184, p.544-553
Hauptverfasser: Shi, Mengjiao, Jiang, Yuting, Yan, Yingchun, Feng, Jing, Wei, Tong, Zhang, Mingyi, Liu, Zheng, Fan, Zhuangjun
Format: Artikel
Sprache:eng
Schlagworte:
Batteries
Chemical bonds
Electrocatalyst
Electron transfer
Graphene
Lithium
Lithium sulfur batteries
Low conductivity
N, S co-doped graphene
Polysulfide absorption
Polysulfides
Porous materials
Porous media
Redox reactions
Stability
Studies
Sulfur
Synergistic effect
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container_end_page 553
container_issue
container_start_page 544
container_title Carbon (New York)
container_volume 184
creator Shi, Mengjiao
Jiang, Yuting
Yan, Yingchun
Feng, Jing
Wei, Tong
Zhang, Mingyi
Liu, Zheng
Fan, Zhuangjun
description The large-scale application of lithium sulfur batteries is impeded by their cycling stability and power performance mainly due to the polysulfide shuttle effect and low conductivity of sulfur. Herein, a multifunctional sulfur host of N/S co-doped porous graphene layered matrix (NSPG) is fabricated. High specific surface area of NSPG can guarantee the homogeneous deposition and high utilization of S/Li2S. Moreover, the layered graphene skeleton with abundant crumples can not only construct efficient channels for fast electrolyte ion/electron transfer but also effectively buffer the volume expansion of S during long-time charge/discharge process. DFT calculations verify that the N/S co-doping can promote the redox reaction rate and inhibit the polysulfides shuttle effect through chemical bonding interaction. Benefiting from the above synergistic effects, the NSPG/S electrode exhibits excellent rate performance (646 mAh g−1 at 10C) and outstanding cycle stability (693 mAh g−1 after 500 cycles). Even at a high mass loading of 4.5 mg cm−2, a capacity of 786 mAh g−1 can be retained after 100 cycles. This work might offer a feasible solution for developing sulfur host with multifunctionality and electrocatalytic activity for high-performance lithium sulfur batteries. The high specific surface area N, S co-doped porous graphene layered matrix (NSPG) with many crumples on the graphene sheets enable high cycle and rate performance as the sulfur hosts for lithium-sulfur batteries because of the strong physicochemical confinement, homogeneous deposition and high utilization of S/Li2S, and abundant ion transport paths. [Display omitted]
doi_str_mv 10.1016/j.carbon.2021.08.046
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Herein, a multifunctional sulfur host of N/S co-doped porous graphene layered matrix (NSPG) is fabricated. High specific surface area of NSPG can guarantee the homogeneous deposition and high utilization of S/Li2S. Moreover, the layered graphene skeleton with abundant crumples can not only construct efficient channels for fast electrolyte ion/electron transfer but also effectively buffer the volume expansion of S during long-time charge/discharge process. DFT calculations verify that the N/S co-doping can promote the redox reaction rate and inhibit the polysulfides shuttle effect through chemical bonding interaction. Benefiting from the above synergistic effects, the NSPG/S electrode exhibits excellent rate performance (646 mAh g−1 at 10C) and outstanding cycle stability (693 mAh g−1 after 500 cycles). Even at a high mass loading of 4.5 mg cm−2, a capacity of 786 mAh g−1 can be retained after 100 cycles. This work might offer a feasible solution for developing sulfur host with multifunctionality and electrocatalytic activity for high-performance lithium sulfur batteries. The high specific surface area N, S co-doped porous graphene layered matrix (NSPG) with many crumples on the graphene sheets enable high cycle and rate performance as the sulfur hosts for lithium-sulfur batteries because of the strong physicochemical confinement, homogeneous deposition and high utilization of S/Li2S, and abundant ion transport paths. 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Herein, a multifunctional sulfur host of N/S co-doped porous graphene layered matrix (NSPG) is fabricated. High specific surface area of NSPG can guarantee the homogeneous deposition and high utilization of S/Li2S. Moreover, the layered graphene skeleton with abundant crumples can not only construct efficient channels for fast electrolyte ion/electron transfer but also effectively buffer the volume expansion of S during long-time charge/discharge process. DFT calculations verify that the N/S co-doping can promote the redox reaction rate and inhibit the polysulfides shuttle effect through chemical bonding interaction. Benefiting from the above synergistic effects, the NSPG/S electrode exhibits excellent rate performance (646 mAh g−1 at 10C) and outstanding cycle stability (693 mAh g−1 after 500 cycles). Even at a high mass loading of 4.5 mg cm−2, a capacity of 786 mAh g−1 can be retained after 100 cycles. This work might offer a feasible solution for developing sulfur host with multifunctionality and electrocatalytic activity for high-performance lithium sulfur batteries. The high specific surface area N, S co-doped porous graphene layered matrix (NSPG) with many crumples on the graphene sheets enable high cycle and rate performance as the sulfur hosts for lithium-sulfur batteries because of the strong physicochemical confinement, homogeneous deposition and high utilization of S/Li2S, and abundant ion transport paths. 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This work might offer a feasible solution for developing sulfur host with multifunctionality and electrocatalytic activity for high-performance lithium sulfur batteries. The high specific surface area N, S co-doped porous graphene layered matrix (NSPG) with many crumples on the graphene sheets enable high cycle and rate performance as the sulfur hosts for lithium-sulfur batteries because of the strong physicochemical confinement, homogeneous deposition and high utilization of S/Li2S, and abundant ion transport paths. [Display omitted]</abstract><cop>New York</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.carbon.2021.08.046</doi><tpages>10</tpages><orcidid>https://orcid.org/0000-0001-5639-0675</orcidid></addata></record>
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subjects Batteries
Chemical bonds
Electrocatalyst
Electron transfer
Graphene
Lithium
Lithium sulfur batteries
Low conductivity
N, S co-doped graphene
Polysulfide absorption
Polysulfides
Porous materials
Porous media
Redox reactions
Stability
Studies
Sulfur
Synergistic effect
title Polarity-induced precipitation of S/Li2S confined into N and S co-doped porous graphene layered matrix for lithium sulfur batteries
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