Impact of Lithium‐Ion Coordination on Lithium Electrodeposition

Sheng, L.; Wu, Yanzhou; Tian, Jiekang; Wang, Li; Wang, Jianlong; Tang, Yaping; Xu, Hong; He, Xiangming

doi:10.1002/eem2.12266

Cited by 8 publications

(10 citation statements)

References 46 publications

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“…As one of the most accessible aspects of battery manufacturing, electrolyte engineering is especially attractive. Relying on knowledge learned from Li–ion battery electrolyte design ( 21 – 23 ), tuning Zn 2+ cation solvation structure by optimizing electrolyte formulations has become a critical and ubiquitous approach to improving Zn anode reversibility, which is especially effective in the case of aqueous electrolytes due to the ability to alter both interfacial structures and solid electrolyte interphase (SEI) chemistries via solvation structures. The emerging superconcentrated “water-in-salt” electrolytes offer opportunities to stabilize the Zn metal anode with a significant amount of salt anions (e.g., > 7 m Cl − [ 7 , 8 ], 20 m bis(trifluoromethylsulfonyl)imide [TFSI − ] [ 9 ]) to partially replace H 2 O in the Zn 2+ solvation sheath, thus suppressing hydrogen evolution, promoting desired Zn–deposition morphology, and improving CE.…”

mentioning

confidence: 99%

Highly reversible Zn metal anode enabled by sustainable hydroxyl chemistry

Vatamanu

Hahn

et al. 2022

Proc. Natl. Acad. Sci. U.S.A.

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Rechargeable Zn metal batteries (RZMBs) may provide a more sustainable and lower-cost alternative to established battery technologies in meeting energy storage applications of the future. However, the most promising electrolytes for RZMBs are generally aqueous and require high concentrations of salt(s) to bring efficiencies toward commercially viable levels and mitigate water-originated parasitic reactions including hydrogen evolution and corrosion. Electrolytes based on nonaqueous solvents are promising for avoiding these issues, but full cell performance demonstrations with solvents other than water have been very limited. To address these challenges, we investigated MeOH as an alternative electrolyte solvent. These MeOH-based electrolytes exhibited exceptional Zn reversibility over a wide temperature range, with a Coulombic efficiency > 99.5% at 50% Zn utilization without cell short-circuit behavior for > 1,800 h. More important, this remarkable performance translates well to Zn || metal-free organic cathode full cells, supporting < 6% capacity decay after > 800 cycles at −40 °C.

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mentioning

confidence: 99%

Highly reversible Zn metal anode enabled by sustainable hydroxyl chemistry

Vatamanu

Hahn

et al. 2022

Proc. Natl. Acad. Sci. U.S.A.

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“…In 2005, a cubic water box containing 216 molecules was simulated using DC-based and HF-type SE methods . The DFTB method was applied along with the DC method in the 2000s to analyze the structure, mechanics, and dynamics of protein, amylose chain, and bulk water systems. − In the last several years, more than 30 computational studies have been reported by utilizing the DCDFTBMD (or its predecessor) program introduced in section . ,− ,,,− ,,− ,,,,− …”

Section: Illustrative Applicationsmentioning

confidence: 99%

“…Theoretical analyses of the structural, mechanical, and dynamical properties have been performed for various battery electrolytes. ,,,,,, The obstacles for the applications were the lack of DFTB parameters for lithium, one of the essential elements of the carrier cation, and the limited accuracy of existing parameters for some anion species. The parametrization issues were addressed by extending and improving the existing parameter set. ,, The insights obtained from large-scale electrolyte systems containing thousands of atoms have assisted the understanding of experimental measurements. ,, The DC-based DFTB-MD simulation is a promising tool for the theoretical design of new electrolytes.…”

Section: Illustrative Applicationsmentioning

confidence: 99%

Divide-and-Conquer Linear-Scaling Quantum Chemical Computations

et al. 2023

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Fragmentation and embedding schemes are of great importance when applying quantum-chemical calculations to more complex and attractive targets. The divide-and-conquer (DC)-based quantum-chemical model is a fragmentation scheme that can be connected to embedding schemes. This feature article explains several DC-based schemes developed by the authors over the last two decades, which was inspired by the pioneering study of DC self-consistent field (SCF) method by Yang and Lee (J. Chem. Phys. 1995, 103, 5674−5678). First, the theoretical aspects of the DC-based SCF, electron correlation, excited-state, and nuclear orbital methods are described, followed by the two-component relativistic theory, quantummechanical molecular dynamics simulation, and the introduction of three programs, including DC-based schemes. Illustrative applications confirmed the accuracy and feasibility of the DC-based schemes.

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“…However, the traditional graphite anode-based LIBs have limited energy density that cannot meet the increasing market demands for a longer cycle life . Compared with the conventional graphite anode, lithium (Li) metal is regarded as the most promising anode material for next-generation rechargeable batteries owing to its high theoretical capacity (3860 mA h/g) and low chemical potential (−3.04 V vs standard hydrogen electrode). , However, lithium metal batteries (LMBs) suffer from undesirable SEI layer formation, uncontrollable Li dendrite growth, and large volumetric changes of Li metal during the Li stripping and Li plating processes. − The Li dendrite growth will expose its high surface area to the electrolyte, which accelerates the consumption of the electrolyte and leads to low Coulomb efficiency. , The uncontrollable Li dendrite formation issue is closely related to the Li plating process, which is affected by the lithiophilic property of the substrate materials.…”

Section: Introductionmentioning

confidence: 99%

“…8−11 The Li dendrite growth will expose its high surface area to the electrolyte, which accelerates the consumption of the electrolyte and leads to low Coulomb efficiency. 12,13 The uncontrollable Li dendrite formation issue is closely related to the Li plating process, which is affected by the lithiophilic property of the substrate materials.…”

Section: ■ Introductionmentioning

confidence: 99%

Regulation of Dendrite-Free Li Plating via Lithiophilic Sites on Lithium-Alloy Surface

Zhang

Wang

et al. 2022

ACS Appl. Mater. Interfaces

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Lithium (Li) deposition behavior plays an important role in dendrite formation and the subsequent performance of lithium metal batteries. This work reveals the impact of the lithiophilic sites of lithium-alloy on the Li plating process via the first-principles calculations. We find that the Li deposition mechanisms on the Li metal and Li22Sn5 surface are different due to the lithiophilic sites. We first propose that Li plating on the Li metal surface goes through the “adsorption–reduction–desorption–heterogeneous nucleation–cluster drop” process, while it undergoes the “adsorption–reduction–growth” process on the Li22Sn5 surface. The lower adsorption energy contributes to the easy adsorption of Li on the lithiophilic sites of the Li22Sn5 surface. The lower Li reduction energy on the Li metal surface indicates that it is easy for Li to be reduced on the Li metal surface, attributed to its higher Fermi energy level. Furthermore, the faster Li diffusion on the Li22Sn5 surface results in smooth Li deposition, which is based on a “two-Li synergy diffusion” mechanism. However, Li diffuses more slowly on the Li metal surface than on the Li22Sn5 surface due to the “single Li diffusion” mechanism. This work provides a fundamental understanding on the impact of lithiophilic sites of Li alloy on the Li plating process and points out that the future design of 3D Li-alloy substrates decorated with multilithiophilic sites can prevent dendrite formation on the lithium-alloy substrate by guiding uniform Li deposition.

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Impact of Lithium‐Ion Coordination on Lithium Electrodeposition

Cited by 8 publications

References 46 publications

Highly reversible Zn metal anode enabled by sustainable hydroxyl chemistry

Highly reversible Zn metal anode enabled by sustainable hydroxyl chemistry

Divide-and-Conquer Linear-Scaling Quantum Chemical Computations

Regulation of Dendrite-Free Li Plating via Lithiophilic Sites on Lithium-Alloy Surface

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