Phenoxy Radical‐Induced Formation of Dual‐Layered Protection Film for High‐Rate and Dendrite‐Free Lithium‐Metal Anodes

Chen, Chao; Liang, Qianwen; Chen, Zhongxin; Zhu, Weiya; Wang, Zejun; Li, Yuan; Wu, Xianwen; Xiong, Xunhui

doi:10.1002/anie.202110441

Cited by 77 publications

(43 citation statements)

References 61 publications

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“…1 However, many problems remain to be solved. 2,3 Increasing concerns for the environment, lack of lithium resources, and the use of toxic organic electrolytes have limited their further applications. 4,5 Compared with the lithium/sodium battery systems, rechargeable aqueous zinc ion batteries (AZIBs) have attracted extensive attention as a promising choice for largescale energy storage systems due to their excellent characteristics, 6 such as high theoretical specic capacity (820 mA h g À1 ), low redox potential (À0.76 V vs. SHE), reasonable price, and simplied assembly.…”

Section: Introductionmentioning

confidence: 99%

A stable fluoride-based interphase for a long cycle Zn metal anode in an aqueous zinc ion battery

Yang

et al. 2022

J. Mater. Chem. A

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Section: Introductionmentioning

confidence: 99%

A stable fluoride-based interphase for a long cycle Zn metal anode in an aqueous zinc ion battery

Yang

et al. 2022

J. Mater. Chem. A

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“…Notably, the peak in the O 1s spectrum located at 528.3 eV (Figure b) may be associated with Li 2 O, which originates from the LiClO 4 additive that facilitates Li + transport and presents a more uniform electric field intensity distribution on the Li anode surface. , Furthermore, the existence of LiCl is further evidenced by the Li 1s spectrum in Figure c, the LiCl peak located around 56.3 eV, the Cl 2p spectrum in Figure d, the LiCl 2p 1/2 peak at 200.5 eV, and the LiCl 2p 3/2 peak at 198.9 eV. The F 1s spectrum in Figure S5 of the Supporting Information found that the LiF content on the surface of the negative electrode containing the most additive additions is relatively low, indicating that the additive addition can effectively reduce the decomposition of the electrolyte. − More importantly, the electrochemical performance is effectively improved by benefiting from a stable and homogeneous SEI layer. The cycling CE in Li||Cu cells and cycle stability in complete cells are used to evaluate the reversibility of the Li metal anode in practical application, which is encouraged by the impressive interfacial strength in symmetric cells. − The CEs of Li||Cu cells are shown in Figure a at current densities of 0.5 and 2 mA cm –2 , respectively, with a fixed deposition capacity of 1 mAh cm –2 .…”

Section: Resultsmentioning

confidence: 92%

Lithium Perchlorate Additive for Dendritic-Free and Long-Life Li Metal Batteries

Deng

et al. 2022

Energy Fuels

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Nowadays, lithium (Li) metal is regarded as the most prospective electrode for the next generation of rechargeable batteries. Regrettably, poor coulombic efficiency (CE) and dendritic lithium development after repeated lithium electroplating/exfoliation treatments significantly restrict Li metal battery applications. To prevent dendrite growth of the Li metal during the reaction, an adequate amount of lithium perchlorate (LiClO4) is added to the ether-based electrolyte as an additive. When this additive is combined with lithium metal, a homogeneous and dense solid electrolyte interphase (SEI) layer rich in lithium chloride and lithium oxide can be created in situ. As a result of the general synergistic protection of LiCl and Li2O, the produced SEI has high ionic conductivity, allowing Li+ mobility, resulting in a more homogeneous distribution of electric field strength, helping to uniform Li deposition, and preventing the development of Li dendrites. As a result, the superior electrochemical performances are demonstrated by an ultralong cycling lifetime (>1500 h) in Li||Li symmetrical cells, coupled with a relatively low hysteresis voltage of 60 mV at 1 mA cm–2, a sufficiently high-quality CE (approximately 96% for 200 cycles at the current density of 0.5 mA cm–2 in Li||Cu cells), and an improved cycling stability in the Li||LiFePO4 complete cell.

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“…The XPS spectra of graphite oxide and 1D-GNS show two major peaks at 282 and 534 eV for the C 1s and O 1s, respectively (Figure S2). Parts C and D of Figure compare the C 1s high-resolution XPS spectra of graphite oxide and 1D-GNS, in which the deconvoluted C 1s spectra of graphite oxide (Figure C) can be resolved into four components centered at 283.8, 285.5, 287.9, and 290.5 eV, representing C–C/CC, C–O–C/C–O, CO, and OC–O, respectively. − In contrast, from the C 1s spectra of 1D-GNS (Figure D), the shrinking or even concealment of the peak area of the oxygen-containing groups can be seen, which can be attributed to the reduction of most of the oxygen-containing groups caused during the high-temperature treatment process in the Ar/H 2 atmosphere. Raman spectra can be used to judge the degree of disorder and graphitization, as shown in Figure E.…”

Section: Resultsmentioning

confidence: 99%

Sodium Sulfate Template-Directed Methodology of Rolling Up a Two-Dimensional Graphene Nanosheet into a One-Dimensional Nanoscroll and Its Anode Performance in a Lithium-Ion Battery

Yin

Yan

et al. 2021

ACS Appl. Energy Mater.

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Graphene nanoscroll has received enormous interest due to its potential applications in various fields. However, in practice there still remains a challenge toward cost-efficiency and scale-up production with the existing advanced experimental techniques. Herein, we report an integration methodology to construct a one-dimensional graphene nanoscroll (1D-GNS) from a two-dimensional graphene nanosheet (2D-rGO) via an ingenious template-directed synthesis approach, in which Na2SO4 was used as a sacrificial template for the first time. Na2SO4 was first generated on the surface of reduced graphene oxide (rGO) nanosheets by a combination of antisolvent self-assembly and heat treatment under moderate temperature, in sequence, to shape and maintain the 2D-rGO architecture into an rGO@Na2SO4 composite, which was then immediately quenched into water to dissolve the Na2SO4 template and meanwhile roll up the 2D graphene nanosheets into 1D nanoscrolls spontaneously, followed by a final thermal reduction to reduce the oxygenous groups. The crimping behavior of the 1D-GNS can be conducted by varying the heat-treatment temperature during the quenching process. The as-synthesized 1D-GNS gives quite good electrochemical stability when evaluated as an anode material in a Li-ion battery. This interesting methodology provides an avenue to design and fabricate other scroll-structured nanoarchitectures.

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Phenoxy Radical‐Induced Formation of Dual‐Layered Protection Film for High‐Rate and Dendrite‐Free Lithium‐Metal Anodes

Cited by 77 publications

References 61 publications

A stable fluoride-based interphase for a long cycle Zn metal anode in an aqueous zinc ion battery

A stable fluoride-based interphase for a long cycle Zn metal anode in an aqueous zinc ion battery

Lithium Perchlorate Additive for Dendritic-Free and Long-Life Li Metal Batteries

Sodium Sulfate Template-Directed Methodology of Rolling Up a Two-Dimensional Graphene Nanosheet into a One-Dimensional Nanoscroll and Its Anode Performance in a Lithium-Ion Battery

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