Elucidating the Electrochemical Activity of Electrolyte-Insoluble Polysulfide Species in Lithium-Sulfur Batteries

Klein, Michael J.; Goossens, Karel; Bielawski, Christopher W.; Manthiram, Arumugam

doi:10.1149/2.0051610jes

Cited by 21 publications

(35 citation statements)

References 37 publications

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“…The same ratio for the unmodified Li 2 S electrode that was assembled into a cell, disassembled, and then washed with TEGDME was significantly less, corresponding to a lower S:Li ratio. Previous studies have noted that commercial Li 2 S powders contain soluble polysulfide impurities . We thus hypothesize that the soluble polysulfides are partially extracted in the uncycled Li 2 S cell, while they are protected by the MnS encapsulant layer in the Li 2 S/Mn cell.…”

Section: Ups Resultsmentioning

confidence: 85%

An Effective Lithium Sulfide Encapsulation Strategy for Stable Lithium–Sulfur Batteries

Klein

Dolocan

et al. 2017

Advanced Energy Materials

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attributed to the insulating nature of sulfur and its discharge product, Li 2 S; (ii) fast capacity decay due to activematerial loss in the form of soluble polysulfide species; and (iii) potential safety hazards arising with the use of lithium metal as an anode.To mitigate the safety concerns of metallic lithium, one approach is to start with Li 2 S and couple it with a lithium-free anode (silicon, tin, or graphite). [14] When employed as a cathode, Li 2 S encounters less volume expansion in the first cycle; however, similar to its sulfur cathode counterpart, it also requires efficient electron transport pathways around the insulating Li 2 S particles and an effective encapsulation to reduce polysulfide dissolution. [15] In 2014, Seh et al. performed pioneering work that successfully encapsulated Li 2 S with a nanocomposite strategy consisting of 2D layered transition-metal disulfides that offered high conductivity and affinity for polysulfides. [16] The nanocomposite cathodes exhibited enhanced activity in LiS batteries as revealed by a lower charging overpotential, and improved cycling stability up to 400 cycles. However, the process utilized nanosized Li 2 S particles and a complex processing scheme requiring hightemperature annealing of the reacted product, among other preparation steps. In addition, hierarchical carbon structures have also been used to encapsulate Li 2 S forming nanocomposites; [17,18] however, their long-term cycling stability remains a concern considering the nonpolar nature of carbon and its lower affinity for polysulfide species with high polarity. [19,20] To date, a low-cost design of a stable, conductive encapsulation architecture for Li 2 S is yet to be realized.In this work, we build an encapsulation layer comprised of transition-metal sulfide on the surface of Li 2 S bulk particles via a facile strategy employing a surface chemical reaction between Li 2 S and an electrolyte additive containing the transition-metal salt. It is demonstrated that the surface ionization energy of the encapsulation layer determines the initial charging overpotential of Li 2 S. Moreover, while most additives generate encapsulation layers in the open-circuit configuration that are unstable during cycling, it is shown that at least one transition-metal additive, containing manganese, forms a stable encapsulation layer consisting of MnS via a chemical reaction with Li 2 S. The stability of such an in-situ-formed encapsulation layer is a result of the MnS compound being chemically inactive within the cycling window. Through this mechanistic analysis, we With a high theoretical capacity of 1162 mA h g −1 , Li 2 S is a promising cathode that can couple with silicon, tin, or graphite anodes for next-generation energy storage devices. Unfortunately, Li 2 S is highly insulating, exhibits large charge overpotential, and suffers from active-material loss as soluble polysulfides during battery cycling. To date, low-cost, scalable synthesis of an electrochemically active Li 2 S cathode remains a challenge. This work ...

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Section: Ups Resultsmentioning

confidence: 85%

An Effective Lithium Sulfide Encapsulation Strategy for Stable Lithium–Sulfur Batteries

Klein

Dolocan

et al. 2017

Advanced Energy Materials

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“…Films with small quantities of soluble sulfur–sulfur species will form polysulfides in solution and the OCV will be in the range of 2.2 ± 0.2 V, as observed for the films in this work over 70 nm thick. The higher OCV (between 1.8 and 1.9 V) for the thin (<90 nm) films than the pure, crystalline Li 2 S reference likely reflect insoluble (Li 2 S 2 -type) solid polysulfides …”

Section: Resultsmentioning

confidence: 80%

“…Similarly, while the conductivity of Li 2 S 2 should be substantially larger than Li 2 S, only half of the theoretical capacity is realizable if the final discharge product of a Li–S battery is Li 2 S 2 . We have shown in the past that solid Li 2 S 2 reduces to Li 2 S only when in intimate contact with the current collector, so we expect that Li 2 S thickness should still be limiting to cell-level capacity.…”

Section: Resultsmentioning

confidence: 99%

Rational Design of Lithium–Sulfur Battery Cathodes Based on Experimentally Determined Maximum Active Material Thickness

2017

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Rational design of conductive carbon hosts for high energy density lithium-sulfur batteries requires an understanding of the fundamental limitations to insulating active material loading. In this work, we investigate the electrochemistry of lithium sulfide films ranging in thickness from 30 to 3500 nm. We show that films thicker than approximately 40 nm cannot be charged at local charge densities above 1 μA cm, and by implication, the maximum useful pore diameter is near 60 nm in a practical cathode. "Activation" overpotentials for LiS are identified in thicker films, resulting from polysulfide generation, but are shown not to improve the fundamental areal charge limitations. We develop a model for filling of conductive pores with active material to rationally design composites based on local charge density. For low-electrolyte applications, the importance of matching micropore volume to sulfide loading and cycling rate is emphasized.

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“…The sulfur cathode in Li-S batteries also relies on a dissolution-precipitation process, and the nonuniform precipitation of insulating Li 2 S from the dissolved LiPSs leads to a high energy barrier for the charging process and blocks the pores in the electrode. [41][42][43] Therefore, we further explored the effects of such a vertical structure with homogeneous Au seeds on the regulation of Li 2 S deposition. The deposition of Li The full cells were also assembled with the Li metal as the anodes and the VG-GP or Au-VG-GP-5 loaded with sulfur as the cathodes (denoted S/VG-GP and S/Au-VG-GP-5).…”

Section: Resultsmentioning

confidence: 99%

Regulating the Stable Lithium and Polysulfide Deposition in Batteries by a Gold Nanoparticle Modified Vertical Graphene Host

Han

Huang

et al. 2021

Adv Energy and Sustain Res

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3D hosts have been widely investigated to stabilize the lithium (Li) metal anode (LMA) for next‐generation high‐energy‐density batteries. However, the complicated porous structure and the lithiophobic framework always lead to nonuniform Li deposition and low host utilization. Herein, Au nanoparticle (NP)–modified vertical graphenes, which are grown on flexible graphite paper, are prepared as the 3D host (denoted Au‐VG‐GP) to guide Li nucleation and deposition. It is shown that the vertical graphene structure with the low tortuosity effectively decreases the ion diffusion resistance and avoids the formation of a concentration gradient, ensuring uniform ion distribution in the 3D host. At the same time, the uniformly distributed Au NPs act as heterogeneous seeds guiding fast and uniform Li nucleation and growth. As a result, the Au‐VG‐GP host effectively stabilizes the LMA and achieves a high Coulombic efficiency in the half‐cells. A small overpotential and long cycling stability are also achieved for the LMA in the symmetrical cells and full batteries with such a host. In addition, such a host can also guide uniform and high‐capacity deposition of Li2S in the cathode of lithium–sulfur batteries, showing its potential uses in energy storage devices based on a dissolution–deposition mechanism.

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Elucidating the Electrochemical Activity of Electrolyte-Insoluble Polysulfide Species in Lithium-Sulfur Batteries

Cited by 21 publications

References 37 publications

An Effective Lithium Sulfide Encapsulation Strategy for Stable Lithium–Sulfur Batteries

An Effective Lithium Sulfide Encapsulation Strategy for Stable Lithium–Sulfur Batteries

Rational Design of Lithium–Sulfur Battery Cathodes Based on Experimentally Determined Maximum Active Material Thickness

Regulating the Stable Lithium and Polysulfide Deposition in Batteries by a Gold Nanoparticle Modified Vertical Graphene Host

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