Electrolyte formulation strategies for potassium‐based batteries

Ni, Ling; Xu, Gaojie; Li, Chuanchuan; Cui, Guanglei

doi:10.1002/exp.20210239

Cited by 27 publications

(24 citation statements)

References 220 publications

(206 reference statements)

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“…Then, varying the interactions of M + –solvent, M + –anion pair, and anion–solvent by changing the type and quantity of solvents, anions, additives, etc., have received significant attention recently to tune the electrolyte properties. − It is worth noting that solvent–solvent interaction has rarely been mentioned before, as such interaction is considered to be very weak, 1–2 orders of magnitude weaker than the ion–ion interaction between M + –anion and the ion-dipole interaction between M + –solvent . However, it is still necessary to make clear the effect of solvent–solvent interactions, as the molar quantity of solvent in the commercial electrolyte is always 10–12 times higher than that of cation and anion when electrolyte with a concentration of 1 M was used. − Therefore, whether the strength of this weak solvent–solvent interaction is sufficient to affect the performance of the electrolyte needs to be paid attention to.…”

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confidence: 99%

Weak Solvent–Solvent Interaction Enables High Stability of Battery Electrolyte

Wang

Cao

et al. 2023

ACS Energy Lett.

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Electrolytes play an important role in transporting metal ions (e.g., Li+) in metal ion batteries, while understanding the relationship between the electrolyte properties and behaviors is still challenging. Herein, we detect the existence of weak solvent–solvent interactions in electrolytes by nuclear magnetic resonance (NMR), particularly discovering that such interactions have a significant function of stabilizing the electrolytes, which has never been reported before. As a paradigm, we renovated the understanding of the role of ethylene carbonate (EC) solvent in the lithium-ion battery electrolyte. We find that the EC solvent can stabilize the linear carbonate solvent electrolyte, particularly the diethyl carbonate (DEC) electrolyte, by the weak intermolecular interactions, enhancing the energy difference between the orbitals of the Li+(EC) x (DEC) y complex, in turn demonstrating strong capability against reduction. Our viewpoint was further demonstrated in other metal ion batteries (e.g., Na+, K+), whose discovery is significant for designing electrolytes and in-depth understanding of the battery performance.

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confidence: 99%

Weak Solvent–Solvent Interaction Enables High Stability of Battery Electrolyte

Wang

Cao

et al. 2023

ACS Energy Lett.

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“…The depth-profiling XPS analysis indicates that the main variation of SEI compositions occurs in the outer layer. Specifically, the O 1s spectra of the Gr-0.01 V anode retrieved from KFeHCF (4.5 V)/Gr (0.01 V) and obtained at 0 s sputtering time show decreased PEDC (potassium ethylene decarbonate, (CH 2 OCO 2 K) 2 ) content (which is decomposed into K 2 CO 3 , Figure i) and increased PEO (poly(ethylene oxide) oligomers, −(CH 2 CH 2 O) n −) content (attributed to the decomposition of EC solvent, Figure j) after cycling. , Meanwhile, its F 1s spectra collected at 0 s sputtering time exhibit decreased the K x PF y O z content, which is found to be decomposed into KF. ,, In contrast, for the Gr-3.0 V anode retrieved from KFeHCF (2.0 V)/Gr (3.0 V), the contents of PEDC and K x PF y O z increased while that of PEO decreased after cycling, which is likely due to the decomposition of EC and KPF 6 to generate PEDC and K x PF y O z , respectively . The presence and uniform distribution of K 2 CO 3 in the SEI in KFeHCF (4.5 V)/Gr (0.01 V) was also identified by the Raman mapping and XRD results (Figure S16).…”

Section: Tailored Design Of Cei/sei For Enhanced K+ Storagementioning

confidence: 98%

Engineering Electrode/Electrolyte Interphase Chemistry toward High-Rate and Long-Life Potassium Ion Full-Cell

et al. 2023

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Controlling the interfacial chemistries of the cathode and anode in potassium ion full-cells is critically important for better K+ storage; however, the correlation between cathode electrolyte interphase (CEI) and solid electrolyte interphase (SEI) and its effect on electrochemical performance is poorly understood, not mention their rational matchup. In this study, an electrochemical modification strategy has been employed for the tailored design of both the CEI on a K2Fe[Fe(CN)6] (KFeHCF) surface and the SEI on a graphite (Gr) surface. The optimized matchup between CEI and SEI realized a good rate and cycling performance in KFeHCF/Gr full-cells, which is attributed to the presence of a robust, homogeneous, and conductive SEI that contains chemically stable PEO (−(CH2CH2O) n −) and K2CO3. Our results not only promoted fundamental understanding of interfacial chemistry on K+ storage, but also provided rational design strategy to realize enhanced efficiency and durability of potassium ion full-cells, which can also be extended to other energy storage systems.

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“…G A 0 is the Gibbs free energy of one A atom in the reference state, namely metallic A. Δ r G is the driving force for the electrochemical decomposition reaction. [52,53] Given the fact that the electric potential Φ is a function of x as determined in A x M y N z , the relationship between Δ r G and Φ can be represented following eqn (5):…”

Section: Theoretical Basis Of Esw Predictionmentioning

confidence: 99%

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confidence: 99%

Reclaiming Neglected Compounds as Promising Solid State Electrolytes by Predicting Electrochemical Stability Window with Dynamically Determined Decomposition Pathway

Lin

et al. 2022

Advanced Energy Materials

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major obstacles in the development of all-solid-state batteries (ASSBs) with high energy density, high intrinsic safety, and long service life. [1][2][3][4][5] Compared with modification (such as doping, [6,7] coating [8][9][10][11][12] ) on well-known SSEs, high-throughput screenings on less-investigated candidate materials with high ion conductivities and wide ESWs can provide a much larger database for SSE selection, thereby tremendously accelerating the development of ASSBs. [13][14][15][16] Recently, the rapid development of materials databases (e.g., Materials Project, [17] Inorganic Crystal Structure Database [18,19] ) has enabled the possibility for such high-throughput screenings. Jun et al. demonstrated the strong predictive power of the corner-sharing structural descriptor in high-throughput screening, leading to the discovery of 10 new oxide frameworks predicted to exhibit superionic conductivity. [15] In our previous work, 1270 possible fast ion conductors with low ionic migration energy barriers [20] were identified from the Inorganic Crystal Structure Database (released 2016/2) [18,19] based on the filter combining geometric analysis [21,22] and bond valence site energy (BVSE) methods. [23,24] However, a critical question still remains in the screening of materials with wide ESWs: how to develop a reliable high-throughput method to predict ESW accurately?The accurate prediction of the electrochemical stability windows (ESWs) enables the rational design of solid state electrolytes (SSEs). Currently, the ESW prediction is based on direct and indirect decomposition analysis methods (DDAM and IDAM). However, DDAM/IDAM can only involve thermodynamically/kinetically favorable decomposition pathway, both resulting in the large deviation between the predicted ESW and the experimental one. Specifically, certain excellent candidate SSEs may be continuously neglected in the highthroughput screening due to underpredicted ESWs. Herein, a high-accuracy ESW prediction method is proposed enabling dynamical determination of the appropriate decomposition pathway by analyzing the electronic conductivities of all direct and indirect decomposition products. Following this, a high-throughput computation is performed on the ESWs of 328 possible fast Li-ion conductors with low ionic migration energy barriers from the previous research, obtaining good agreement with the available experimental results (Li 10 GeP 2 S 12 and Li 7 La 3 Zr 2 O 12 ). Furthermore, six previously neglected fluorides exhibiting ESWs over 4 V, oxidation potentials exceeding 6 V, excellent phase stability, and interfacial compatibility with seven typical cathodes are reclaimed as promising SSEs. This work demonstrates a strategy to accelerate the SSE development by improving the accuracy of the ESW prediction and enlarging the database of promising SSEs.

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Electrolyte formulation strategies for potassium‐based batteries

Cited by 27 publications

References 220 publications

Weak Solvent–Solvent Interaction Enables High Stability of Battery Electrolyte

Weak Solvent–Solvent Interaction Enables High Stability of Battery Electrolyte

Engineering Electrode/Electrolyte Interphase Chemistry toward High-Rate and Long-Life Potassium Ion Full-Cell

Reclaiming Neglected Compounds as Promising Solid State Electrolytes by Predicting Electrochemical Stability Window with Dynamically Determined Decomposition Pathway

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