Rational Design of Li‐Wicking Hosts for Ultrafast Fabrication of Flexible and Stable Lithium Metal Anodes

Rational Design of Li‐Wicking Hosts for Ultrafast Fabrication of Flexible and Stable Lithium Metal Anodes

The ever‐increasing development of flexible and wearable electronics has imposed unprecedented demand on flexible batteries of high energy density and excellent mechanical stability. Rechargeable lithium (Li) metal battery shows great advantages in terms of its high theoretical energy density. Howev...

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Veröffentlicht in:Small (Weinheim an der Bergstrasse, Germany) Germany), 2022-01, Vol.18 (2), p.e2105308-n/a
Hauptverfasser: Chang, Jian, Hu, Hong, Shang, Jian, Fang, Ruopian, Shou, Dahua, Xie, Chuan, Gao, Yuan, Yang, Yu, Zhuang, Qiu Na, Lu, Xi, Zhang, Yao Kang, Li, Feng, Zheng, Zijian
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Sprache:eng
Schlagworte:
Anodes
Capillary Action
Charging
Dendritic structure
Electrodes
Electronics
Flexibility
flexible batteries
Flux density
interface
Lithium
lithium metal
Nanotechnology
Rechargeable batteries
Stability
textile
wicking
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container_issue 2
container_start_page e2105308
container_title Small (Weinheim an der Bergstrasse, Germany)
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creator Chang, Jian
Hu, Hong
Shang, Jian
Fang, Ruopian
Shou, Dahua
Xie, Chuan
Gao, Yuan
Yang, Yu
Zhuang, Qiu Na
Lu, Xi
Zhang, Yao Kang
Li, Feng
Zheng, Zijian
description The ever‐increasing development of flexible and wearable electronics has imposed unprecedented demand on flexible batteries of high energy density and excellent mechanical stability. Rechargeable lithium (Li) metal battery shows great advantages in terms of its high theoretical energy density. However, the use of Li metal anode for flexible batteries faces huge challenges in terms of its undesirable dendrite growth, poor mechanical flexibility, and slow fabrication speed. Here, a highly scalable Li‐wicking strategy is reported that allows ultrafast fabrication of mechanically flexible and electrochemically stable Li metal anodes. Through the rational design of the interface and structure of the wicking host, the mean speed of Li‐wicking reaches 10 m2 min−1, which is 1000 to 100 000 fold faster than the reported electrochemical deposition or thermal infusion methods and meets the industrial fabrication speed. Importantly, the Li‐wicking process results in a unique 3D Li metal structure, which not only offers remarkable flexibility but also suppresses the dendrite formation. Paring the Li metal anode with lithium‐iron phosphate or sulfur cathode yields flexible full cells that possess a high charging rate (8.0 mA cm−2), high energy density (300–380 Wh kg−1), long cycling stability (over 550 cycles), and excellent mechanical robustness (500 bending cycles). A highly scalable lithium (Li)‐wicking strategy is reported for ultrafast fabrication of mechanically flexible and electrochemically stable Li metal anodes. Through the rational design of the interface and structure of the wicking host, the mean speed of Li‐wicking reaches 10 m2 min−1, which is 1000 to 100000 fold faster than the reported electrochemical deposition or thermal infusion methods and meets the industrial fabrication speed.
doi_str_mv 10.1002/smll.202105308
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Rechargeable lithium (Li) metal battery shows great advantages in terms of its high theoretical energy density. However, the use of Li metal anode for flexible batteries faces huge challenges in terms of its undesirable dendrite growth, poor mechanical flexibility, and slow fabrication speed. Here, a highly scalable Li‐wicking strategy is reported that allows ultrafast fabrication of mechanically flexible and electrochemically stable Li metal anodes. Through the rational design of the interface and structure of the wicking host, the mean speed of Li‐wicking reaches 10 m2 min−1, which is 1000 to 100 000 fold faster than the reported electrochemical deposition or thermal infusion methods and meets the industrial fabrication speed. Importantly, the Li‐wicking process results in a unique 3D Li metal structure, which not only offers remarkable flexibility but also suppresses the dendrite formation. Paring the Li metal anode with lithium‐iron phosphate or sulfur cathode yields flexible full cells that possess a high charging rate (8.0 mA cm−2), high energy density (300–380 Wh kg−1), long cycling stability (over 550 cycles), and excellent mechanical robustness (500 bending cycles). A highly scalable lithium (Li)‐wicking strategy is reported for ultrafast fabrication of mechanically flexible and electrochemically stable Li metal anodes. 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Paring the Li metal anode with lithium‐iron phosphate or sulfur cathode yields flexible full cells that possess a high charging rate (8.0 mA cm−2), high energy density (300–380 Wh kg−1), long cycling stability (over 550 cycles), and excellent mechanical robustness (500 bending cycles). A highly scalable lithium (Li)‐wicking strategy is reported for ultrafast fabrication of mechanically flexible and electrochemically stable Li metal anodes. 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Rechargeable lithium (Li) metal battery shows great advantages in terms of its high theoretical energy density. However, the use of Li metal anode for flexible batteries faces huge challenges in terms of its undesirable dendrite growth, poor mechanical flexibility, and slow fabrication speed. Here, a highly scalable Li‐wicking strategy is reported that allows ultrafast fabrication of mechanically flexible and electrochemically stable Li metal anodes. Through the rational design of the interface and structure of the wicking host, the mean speed of Li‐wicking reaches 10 m2 min−1, which is 1000 to 100 000 fold faster than the reported electrochemical deposition or thermal infusion methods and meets the industrial fabrication speed. Importantly, the Li‐wicking process results in a unique 3D Li metal structure, which not only offers remarkable flexibility but also suppresses the dendrite formation. Paring the Li metal anode with lithium‐iron phosphate or sulfur cathode yields flexible full cells that possess a high charging rate (8.0 mA cm−2), high energy density (300–380 Wh kg−1), long cycling stability (over 550 cycles), and excellent mechanical robustness (500 bending cycles). A highly scalable lithium (Li)‐wicking strategy is reported for ultrafast fabrication of mechanically flexible and electrochemically stable Li metal anodes. Through the rational design of the interface and structure of the wicking host, the mean speed of Li‐wicking reaches 10 m2 min−1, which is 1000 to 100000 fold faster than the reported electrochemical deposition or thermal infusion methods and meets the industrial fabrication speed.</abstract><cop>Germany</cop><pub>Wiley Subscription Services, Inc</pub><pmid>34741427</pmid><doi>10.1002/smll.202105308</doi><tpages>11</tpages><orcidid>https://orcid.org/0000-0003-3327-7543</orcidid><orcidid>https://orcid.org/0000-0002-6653-7594</orcidid></addata></record>
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source MEDLINE; Wiley Online Library Journals Frontfile Complete
subjects Anodes
Capillary Action
Charging
Dendritic structure
Electrodes
Electronics
Flexibility
flexible batteries
Flux density
interface
Lithium
lithium metal
Nanotechnology
Rechargeable batteries
Stability
textile
wicking
title Rational Design of Li‐Wicking Hosts for Ultrafast Fabrication of Flexible and Stable Lithium Metal Anodes
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