2019
DOI: 10.1002/aenm.201901940
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MoN Supported on Graphene as a Bifunctional Interlayer for Advanced Li‐S Batteries

Abstract: drastically superior specific energy density. [1][2][3][4][5][6][7] However, the successful implementation of Li-S batteries is still hindered by many challenges. One of the largest problems facing the current Li-S battery is the rapid capacity decay and serious selfdischarge caused by the dissolution and migration of intermediate lithium polysulfides (LiPSs). [8][9][10][11][12][13][14][15] Significant efforts have been dedicated to the research of suitable approach to address polysulfide shuttling. As one of … Show more

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Cited by 204 publications
(156 citation statements)
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“…[ 58 ] Moreover, sulfur is low cost and environmentally benign. [ 59 ] However, several challenges hinder their applications including the poor electrical conductivity of sulfur and Li 2 S, high solubility of polysulfide and large volume change of 80%, [ 4c ] which lead to low rate capacity, poor Coulomb efficiency, and fast capacity degradation. [ 60 ] Due to the high electrical conductivity, porous structure, and excellent mechanical stability, porous carbon nanomaterials are widely chosen as sulfur hosts, which can enable fast electron transport, effective ion diffusion, good accommodation of volume change, and absorption of polysulfide.…”
Section: Examples For Battery Applicationsmentioning
confidence: 99%
“…[ 58 ] Moreover, sulfur is low cost and environmentally benign. [ 59 ] However, several challenges hinder their applications including the poor electrical conductivity of sulfur and Li 2 S, high solubility of polysulfide and large volume change of 80%, [ 4c ] which lead to low rate capacity, poor Coulomb efficiency, and fast capacity degradation. [ 60 ] Due to the high electrical conductivity, porous structure, and excellent mechanical stability, porous carbon nanomaterials are widely chosen as sulfur hosts, which can enable fast electron transport, effective ion diffusion, good accommodation of volume change, and absorption of polysulfide.…”
Section: Examples For Battery Applicationsmentioning
confidence: 99%
“…After several cycles of CV, the EIS consist of two semicircles at high/middle frequency and a slop line at low frequency ( Figures S3 and S4, Supporting Information), presenting charge-transfer, adsorption, and diffusion processes. [8,33] Evidently, the resistance of charge transfer, adsorption, and diffusion of LiPSs in LSBs with FeOOH interlayer is obviously smaller, suggesting promoted redox conversion of intermediate LiPSs with conductive FeOOH.…”
Section: Resultsmentioning
confidence: 99%
“…In contrast, LSBs with FeOOH/PP separator display a lower potential barrier at 2.194 V, indicating lower solid-liquid conversion barrier catalyzed by FeOOH interlayer. [8,16,39] The catalytic redox conversion can be more clearly revealed by rate capability, which related to fast charge transfer and reversible multiphase conversion especially at high rates. [27] As depicted in Figure 7d, LSBs with FeOOH/PP separator exhibit reversible discharge capacity of 1294 (0.1 C), 1139 (0.2 C), 810 (0.5 C), 730 (1 C), and 449 (2 C) mAh g −1 .…”
Section: Resultsmentioning
confidence: 99%
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“…The CV curve shows that Co4N nanoparticles can catalyze the conversion of Li2S6 to Li2S2 and Li2S, reducing the polarizability (Figure 5e). Da Tian and co-workers developed a separator material of MoN-G/PP [46]. Figure 5f shows the adsorption activation of Li 2 S on MoN.…”
Section: Nitridesmentioning
confidence: 99%