Progress and Prospect of Organic Electrocatalysts in Lithium−Sulfur Batteries

Dong, Yangyang; Li, Tingting; Cai, Dong; Yang, Shuo; Zhou, Xuemei; Nie, Huagui; Yang, Zhi

doi:10.3389/fchem.2021.703354

Cited by 8 publications

(3 citation statements)

References 159 publications

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“…In light of this, homogeneous catalysts capable of realizing solution-regulated reaction pathways exhibit unique advantages over heterogeneous catalysts in LiPSs conversion and Li 2 S deposition. [18,19] Most recently, inorganic additives (such as iodide and metallocene derivates) [20][21][22] and organic molecular (such as Schiff bases, conjugated quinones, and disulfide organics) [23][24][25][26] have been applied to realize the homogenous catalysis in Li-S batteries. Compared with the inorganic additives, organic molecules show the advantage of the stability of the working potential window.…”

Section: Introductionmentioning

confidence: 99%

Self‐Assembled Macrocyclic Copper Complex Enables Homogeneous Catalysis for High‐Loading Lithium–Sulfur Batteries

Huang

Zheng

et al. 2023

Advanced Materials

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The practical viability of high‐energy‐density lithium–sulfur (Li–S) batteries stipulates the use of a high‐loading cathode and lean electrolyte. However, under such harsh conditions, the liquid–solid sulfur redox reaction is much retarded due to the poor sulfur and polysulfides utilization, leading to low capacity and fast fading. Herein, a self‐assembled macrocyclic Cu(II) complex (CuL) is designed as an effective catalyst to homogenize and maximize the liquid‐involving reaction. The Cu(II) ion coordinated with four N atoms features a planar normaldsp2${\mathrm{d}}_{{\mathrm{sp}}^{2}}$ hybridization, showing a strong bonding affinity toward lithium polysulfides (LiPSs) along the normaldz2${\mathrm{d}}_{{z}^{2}}$ orbital via steric effects. Such a structure not only lowers the energy barrier of the liquid–solid conversion (Li2S4 to Li2S2) but also guides a 3D deposition of Li2S2/Li2S. As such, with a 1 wt% electrolyte additive of CuL, a high initial capacity of 925 mAh g−1 and areal capacity of 9.62 mAh cm−2 with a low decay of 0.3%/cycle can be achieved under a high sulfur loading of 10.4 mg cm−2 and low electrolyte/sulfur ratio of 6 µL mgs−1. This work is expected to inspire the design of homogenous catalysts and accelerate the uptake of high‐energy‐density Li–S batteries.

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Section: Introductionmentioning

confidence: 99%

Self‐Assembled Macrocyclic Copper Complex Enables Homogeneous Catalysis for High‐Loading Lithium–Sulfur Batteries

Huang

Zheng

et al. 2023

Advanced Materials

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“…[ 18 ] Moreover, they also reduce the contact between long‐chain LiPSs and electrolytes during charge/discharge cycles. [ 19 ] To date, various catalytic materials, such as metal (Ni, Mo, and Co), [ 20 ] metal oxides (TiO 2 , Co 3 O 4 , and Fe 3 O 4 ), [ 21 ] metal sulfides (Co 9 S 8 , MoS 2 , and TiS 2 ), [ 22,23 ] metal nitrides (TiN and VN), [ 24 ] metal phosphides (CoP, Ni 2 P, and Cu 3 P), [ 25 ] and metal carbides (TiC, Mo 2 C, and Fe 3 C) have been studied as cathode host materials. [ 2 ] The published literature on Li–S battery electrocatalysts has also grown exponentially since 2012, with the trend shown in Figure 1A.…”

Section: Introductionmentioning

confidence: 99%

Direct ink writing of metal‐based electrocatalysts for Li–S batteries with efficient polysulfide conversion

Meng

Geng

et al. 2023

Interdisciplinary Materials

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Thanks to the significantly higher energy density compared with universal commercialized Li‐ion batteries, lithium–sulfur (Li–S) batteries are being investigated for use in prospective energy storage devices. However, the inadequate electrochemical kinetics of reactants and intermediates hinder commercial utilization. This limitation results in substantial capacity degradation and short battery lifespans, thereby impeding the battery's power export. Meanwhile, the capacity attenuation induced by the undesirable shuttle effect further hinders their industrialization. Considerable effort has been invested in developing electrocatalysts to fix lithium polysulfides and boost their conversion effectively. In the conventional process, the planar electrodes are prepared by slurry‐casting, which limits the electron and ion transfer paths, especially when the thickness of the electrodes is relatively large. Compared with traditional manufacturing methods, direct ink writing (DIW) technology offers unique advantages in both geometry shaping and rapid prototyping, and even complex three‐dimensional structures with high sulfur loading. Hence, this review presents a detailed description of the current developments in terms of Li–S batteries in DIW of metal‐based electrocatalysts. A thorough exploration of the behavior chemistry of electrocatalysis is provided, and the adhibition of metal‐based catalysts used for Li–S batteries is summarized from the aspect of material usage and performance enhancement. Then, the working principle of DIW technology and the requirements of used inks are presented, with a detailed focus on the latest advancements in DIW of metal‐based catalysts in Li–S battery systems. Their challenges and prospects are discussed to guide their future development.

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“…The resulting sluggish depletion of soluble LiPSs to Li 2 S 2 /Li 2 S precipitates, accompanied by the rapid generation of LiPSs (S 8 → LiPSs), leads to LiPS accumulation in the electrolyte. This causes large amounts of sulfur species to lose intimate contact with the electrode, which hinders electron/ion transport and potentially risks Li anode corrosion. , Accordingly, modulating sulfur reduction reactions (SRR), especially the conversion of LiPSs to Li 2 S, which accounts for more than 75% of the total capacity, to rapidly decrease the LiPS concentration in the electrolyte has received research attention. − Therefore, designing highly efficient SRR catalysts and developing SRR concepts are important for improving Li–S battery performance.…”

Section: Introductionmentioning

confidence: 99%

Sulfur Reduction Catalyst Design Inspired by Elemental Periodic Expansion Concept for Lithium–Sulfur Batteries

Dong

Cai

et al. 2022

ACS Nano

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The key challenges facing the commercialization of lithium–sulfur (Li–S) batteries are shortening the lithium polysulfide (LiPS) intermediate existence time while accelerating solid-phase conversion reactions. Herein, inspired by highly efficient natural enzymes with Fe/N active sites for oxygen reduction reactions, we report a periodic expansion catalysis concept, i.e., Ru and P synergic stereoselectivity, for designing sulfur reduction reaction (SRR) catalysts. As a proof of concept, a RuP2-configuration molecular catalyst was exploited to assemble an interlayer in Li–S batteries that adsorbs LiPSs, optimizes Li+ migration paths, and catalyzes SRRs. Comprehensive investigation identified the elimination of steric hindrance and strong electron orbital couplings between metallic d band and nonmetallic p band as the main contributing factors of PEC for the SRRs. As a result, the Li–S battery with ∼0.5 wt % catalyst additive showed enhanced cycling stability even under a high sulfur loading (6.5 mg cm–2) and low electrolyte/sulfur ratio (9 μL mg–1).

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Progress and Prospect of Organic Electrocatalysts in Lithium−Sulfur Batteries

Cited by 8 publications

References 159 publications

Self‐Assembled Macrocyclic Copper Complex Enables Homogeneous Catalysis for High‐Loading Lithium–Sulfur Batteries

Self‐Assembled Macrocyclic Copper Complex Enables Homogeneous Catalysis for High‐Loading Lithium–Sulfur Batteries

Direct ink writing of metal‐based electrocatalysts for Li–S batteries with efficient polysulfide conversion

Sulfur Reduction Catalyst Design Inspired by Elemental Periodic Expansion Concept for Lithium–Sulfur Batteries

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