Structure‐Reactivity Relationships of Methylated Tetrahydrofurans with Lithium

Goldman, J. L.; Mank, R; Young, John H.; Koch, V. R.

doi:10.1149/1.2129931

Cited by 106 publications

(41 citation statements)

References 23 publications

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“…While modest improvement (CE = 83.6%, 1977) was subsequently achievable using additives 11 , carbonate solvents are particularly unstable at Li potentials due to their strongly polar carbon-oxygen bonds and inability to form a protective SEI 12 . Thus, replacing carbonates with weakly polar, more cathodically stable ethers led to more substantial increases in CE [13][14][15][16][17][18][19][20] . This era also saw growing use of LiAsF 6 due to its improved safety over LiClO 4 and ability to passivate Al current collectors at cathode potentials 6 .…”

Section: Electrolyte Trends and Strategies Leading To High Cementioning

confidence: 98%

“…This era also saw growing use of LiAsF 6 due to its improved safety over LiClO 4 and ability to passivate Al current collectors at cathode potentials 6 . For example, 1 M LiAsF 6 in tetrahydrofuran (THF) achieved a CE of 89.4% (1978) 13 , motivating use of more-stable 2-methyl-tetrahydrofuran (with 1-1.5 M LiAsF 6 salt), which reached a CE of 97.4% in the following year 15,17 . Later, ether-based blends were introduced, such as LiAsF 6 in diethyl ether (DEE)/THF (CE = 97.6%, 1982) 16 or ether/carbonate cosolvents having ethers as the primary constituent (for example, 1 M LiAsF 6 in 12% PC or 30-35% EC in 1,3-dioxolane (DOL), CE ≈ 98%, 1992) 20 .…”

Section: Electrolyte Trends and Strategies Leading To High Cementioning

confidence: 99%

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Moving beyond 99.9% Coulombic efficiency for lithium anodes in liquid electrolytes

et al. 2021

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Section: Electrolyte Trends and Strategies Leading To High Cementioning

confidence: 98%

Section: Electrolyte Trends and Strategies Leading To High Cementioning

confidence: 99%

Moving beyond 99.9% Coulombic efficiency for lithium anodes in liquid electrolytes

et al. 2021

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“…A hump approximately at 0.5 V (vs Li/Li § was always present during galvanostatic deposition of Li on CO2 adsorbed Ni substrates both in LiCIO~ and LiPF, electrolytes. This is probably due to the formation of Li2CO~ as in [12]. …”

Section: Resultsmentioning

confidence: 98%

Electrochemical behaviors of li electrode in organic electrolytes

Jo¹,

Kwon²,

Chang³

et al. 1997

Metals and Materials

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Characterizations of the morphology of lithium deposited in organic electrolytes were carried out using Ni substrates pretreated with H: and CO2 gases prior to electrodeposition. The electrolytes used were 1 M LiC1OdEC-2MeTHF and 1 M LiPFJEC-2MeTHF. Based on electrochemical measurements, XPS and SEM analyses, it seems that the morphology of lithium during electrodeposition is related to the physical propenies of the electrolyte itself rather than the chemical composition of a passive layer formed on the lithium surface.

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“…In these experiments, five different additives were selected from the list of fourteen chemical compounds shown in Table 1, all of which are representative lithium salts and other additives previously described in the literature. Employing a method already described in a prior paper 18 , the coulombic efficiency (CE) of each cell containing five additives was quantitatively evaluated according to the protocol shown in Fig. 2.…”

Section: Resultsmentioning

confidence: 99%

High-throughput combinatorial screening of multi-component electrolyte additives to improve the performance of Li metal secondary batteries

Matsuda

Nishioka

Nakanishi

2019

Sci Rep

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Data-driven material discovery has recently become popular in the field of next-generation secondary batteries. However, it is important to obtain large, high quality data sets to apply data-driven methods such as evolutionary algorithms or Bayesian optimization. Combinatorial high-throughput techniques are an effective approach to obtaining large data sets together with reliable quality. In the present study, we developed a combinatorial high-throughput system (HTS) with a throughput of 400 samples/day. The aim was to identify suitable combinations of additives to improve the performance of lithium metal electrodes for use in lithium batteries. Based on the high-throughput screening of 2002 samples, a specific combination of five additives was selected that drastically improved the coulombic efficiency (CE) of a lithium metal electrode. Importantly, the CE was remarkably decreased merely by removing one of these components, highlighting the synergistic basis of this mixture. The results of this study show that the HTS presented herein is a viable means of accelerating the discovery of ideal yet complex electrolytes with multiple components that are very difficult to identify via conventional bottom-up approach.

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Structure‐Reactivity Relationships of Methylated Tetrahydrofurans with Lithium

Cited by 106 publications

References 23 publications

Moving beyond 99.9% Coulombic efficiency for lithium anodes in liquid electrolytes

Moving beyond 99.9% Coulombic efficiency for lithium anodes in liquid electrolytes

Electrochemical behaviors of li electrode in organic electrolytes

High-throughput combinatorial screening of multi-component electrolyte additives to improve the performance of Li metal secondary batteries

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