Hexafluoroisopropyl Trifluoromethanesulfonate‐Driven Easily Li<sup>+</sup> Desolvated Electrolyte to Afford Li||NCM811 Cells with Efficient Anode/Cathode Electrolyte Interphases

Li, Xin; Liu, Jiandong; He, Jian; Wang, Huaping; Qi, Shihan; Wu, Daxiong; Huang, Junda; Li, Fang; Hu, Wei; Ma, Jianmin

doi:10.1002/adfm.202104395

Cited by 81 publications

(46 citation statements)

References 43 publications

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“…In addition, the unstable SEI will also induce uneven ionic diffusion and Li deposition, which would result in uncontrolled dendrite growth and poor electrochemical performance. [9][10][11] Therefore, high-quality SEI is highly desired for superior LMBs.Recently, extensive efforts have been devoted to stabilizing Li anode by engineering a robust SEI mainly through electrolyte formulation [12][13][14][15][16] and artificial SEI. [17][18][19][20] However, the role of the structures and components of SEI has long been debated, and the transport mechanism of Li + ions in the SEI is still not well understood.…”

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confidence: 99%

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Li₂CO₃/LiF‐Rich Heterostructured Solid Electrolyte Interphase with Superior Lithiophilic and Li⁺‐Transferred Characteristics via Adjusting Electrolyte Additives

Liu

et al. 2022

Advanced Energy Materials

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147

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The structure and components of solid electrolyte interphase (SEI) is crucial to direct the growth of lithium particles. However, it is hard to have control over them. Herein, an SEI that shares the properties of Li2CO3‐rich and LiF‐rich types is realized by using different fluorine phenylphospines, and constructing a Li2CO3/LiF‐rich heterostructured SEI by using tris(4‐fluorophenyl)phosphine (TFPP) as the electrolyte additive. The well‐balanced SEI formed in TFPP‐containing electrolyte has the fast Li+ transport kinetics of Li2CO3, good electron insulator capability of LiF, and strong affinity toward Li+. It can effectively guarantee fast, uniform Li+ flux through the SEI while preventing electrons from the Li anode entering into SEI, and thus realizes uniform and dense Li deposition at the SEI/Li interface. As expected, the Li anode with TFPP‐containing electrolyte achieves a stable Li plating/stripping over 400 h at 1mA cm−2 while the full cell with a high‐voltage LiNi0.6Co0.2Mn0.2O2 cathode also enables long‐term stability with a capacity retention (87.8% after 200 cycles) at 0.1 A g−1 and excellent rate performance.

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confidence: 99%

“…Recently, extensive efforts have been devoted to stabilizing Li anode by engineering a robust SEI mainly through electrolyte formulation [12][13][14][15][16] and artificial SEI. [17][18][19][20] However, the role of the structures and components of SEI has long been debated, and the transport mechanism of Li + ions in the SEI is still not well understood.…”

mentioning

confidence: 99%

Li₂CO₃/LiF‐Rich Heterostructured Solid Electrolyte Interphase with Superior Lithiophilic and Li⁺‐Transferred Characteristics via Adjusting Electrolyte Additives

Liu

et al. 2022

Advanced Energy Materials

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147

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“…The mass loadings of DC− C/SS, PC−C/SS, and C−C/SS electrodes were controlled at ∼1 mg cm −2 (detailed mass loadings are displayed in Figure S2). The glass microfiber was used as a separator, and a metal potassium was used as 27,28 The cathode was precycled 5 times in the potassium half-cell at 0.2 A g −1 and then discharged to 2.0 V. Meanwhile, the anode was also precycled for 5 cycles. 29−31 3.…”

Section: Methodsmentioning

confidence: 99%

“…The mass ratio of the cathode and anode was controlled at ∼3.2:1. Because the formation of SEI/CEI (CEI = cathode electrolyte interface) caused irreversible capacity in the first cycle, the anode and cathode were precycled to eliminate the irreversible capacity in the first cycle. , The cathode was precycled 5 times in the potassium half-cell at 0.2 A g –1 and then discharged to 2.0 V. Meanwhile, the anode was also precycled for 5 cycles. − …”

Section: Experimental Sectionmentioning

confidence: 99%

Guiding Fabrication of Continuous Carbon-Confined Sb₂Se₃ Nanoparticle Structure for Durable Potassium-Storage Performance

Guo

Cao

Huang

et al. 2021

ACS Appl. Energy Mater.

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Pulverization usually leads to significant solid electrolyte interface (SEI) formation, weak electrochemical contact, and sluggish K+-transmission kinetics. These adverse effects limit the K+-transfer reversibility, endangering the potassium-storage performance. Reported carbon composite structures are insufficient in effectively solving this issue, exhibiting limited cycling performance. Hence, we fabricated a continuous carbon-confined Sb2Se3 nanoparticle composite structure. As expected, this structure achieves a high capacity of 410 mA h g–1 after 1000 cycles with a capacity decay ratio of 0.07% per cycle. In the full cell, this structure still shows a high energy density of 181.4 Wh kg–1. Analysis results reveal that the continuous carbon-confined nanoparticle structure can effectively inhibit pulverization, providing continuous SEI, good electrochemical contact, and a fast K+-diffusion rate. These advantages provide abundant paths for reversible K+ insertion/extraction, accelerate rapid and continuous K+ transmission in electrode, and eventually result in highly reversible K+ transmission in the repeated cycling process. This work indicates that constructing a continuous carbon-confined nanoparticle structure can effectively inhibit adverse effects caused by pulverization for pursuing durable potassium-storage performance.

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“…However, their cycling performance is hindered by the growth of Li dendrites and low Coulombic efficiency (CE). [1][2][3][4][5] Solid electrolyte interphase (SEI) is considered to play crucial roles in repressing the growth of Li dendrites. [6][7][8][9] An ideal SEI film should have two major functions, i.e., anode passivation blocking side reactions between Li metal and electrolyte [10] and facilitating the transmission of Li + through the SEI layer.…”

Section: Introductionmentioning

confidence: 99%

Unveiling the Role of Li⁺ Solvation Structures with Commercial Carbonates in the Formation of Solid Electrolyte Interphase for Lithium Metal Batteries

Wang

Zhou

et al. 2021

Small Methods

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which can be easily cracked by Li dendrites. [13] Extensive effort has been devoted to solving this problem, including artificial SEI films, [14,15] polymers, [16,17] or solid-state electrolytes, [18][19][20] and the electrolyte additives. [21][22][23][24][25][26][27] Due to the convenience and low cost of electrolyte additives, available carbonate-based additives, i.e., fluoroethylene carbonate (FEC), vinyl ethylene carbonate (VEC), vinylene carbonate (VC), and other additives have been widely used. [28][29][30][31][32][33] In addition, much effort has been devoted to revealing the formation mechanism and structures of SEI through advanced characterizations and theoretical calculations in the past four decades. For example, Hu et al. theoretically proposed that the reduction products of VEC on graphite surface were probably composed of LiORCO 2 RO-CO 2 Li, Li 2 CO 3 , LiROCO 2 Li, (ROCO 2 Li) 2 , etc. (R = alkyl group). [34] Lucht and coworkers confirmed the decomposition mechanism that FEC was reduced to form polymerized VC and LiF. [35] Experimentally, SEI structures were revealed by some technologies, including scanning electron microscope (SEM), transmission electron microscope (TEM), X-ray photoelectron spectroscopy (XPS), etc. [28,36,37,21] However, the direct reduction-structure relationship between additives and SEI is not well clarified. The connection among thermodynamics, kinetics, SEI structure, and battery performance for carbonate-based additives is far not understood.Before EC was used on graphite anode, PC was the most widely used in early lithium ion batteries, which is highly compliable with the metal anode. In order to reveal the impact of carbonate-based additives on the SEI and cycling performance, we here chose EC, FEC, VEC, and VC as model additives, and the 1 m LiPF 6 /PC as the blank electrolyte. The theoretical calculations and XPS characterizations demonstrated that electronic structures of Li + -coordinated additives significantly changed and became the main SEI participant, rather than additives. The Li + -coordinated FEC participated in SEI formation and tended to produce LiF-rich SEI, whereas the VEC tended to generate Li 2 CO 3 -rich SEI. Both the "LiF-rich" and "Li 2 CO 3 -rich" SEI layers could effectively boost the cycling performance of Li||Li symmetrical cells. In addition, Li + -coordinated additives Solid electrolyte interphase (SEI), determined by the components of electrolytes, can endow batteries with the ability to repress the growth of Li dendrites. Nevertheless, the mechanism of commercial carbonates on in situgenerated SEI and the consequential effect on cycling performance is not well understood yet, although some carbonates are well used in electrolytes. In this work, quantum chemical calculations and molecular dynamics are used to reveal the formation mechanisms of SEI with carbonate-based electrolyte additives on the atomic level. It is confirmed that the Li-coordinated carbonate species are the leading participant of SEI formation and their impact on battery per...

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Hexafluoroisopropyl Trifluoromethanesulfonate‐Driven Easily Li⁺ Desolvated Electrolyte to Afford Li||NCM811 Cells with Efficient Anode/Cathode Electrolyte Interphases

Cited by 81 publications

References 43 publications

Li₂CO₃/LiF‐Rich Heterostructured Solid Electrolyte Interphase with Superior Lithiophilic and Li⁺‐Transferred Characteristics via Adjusting Electrolyte Additives

Li₂CO₃/LiF‐Rich Heterostructured Solid Electrolyte Interphase with Superior Lithiophilic and Li⁺‐Transferred Characteristics via Adjusting Electrolyte Additives

Guiding Fabrication of Continuous Carbon-Confined Sb₂Se₃ Nanoparticle Structure for Durable Potassium-Storage Performance

Unveiling the Role of Li⁺ Solvation Structures with Commercial Carbonates in the Formation of Solid Electrolyte Interphase for Lithium Metal Batteries

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Hexafluoroisopropyl Trifluoromethanesulfonate‐Driven Easily Li+ Desolvated Electrolyte to Afford Li||NCM811 Cells with Efficient Anode/Cathode Electrolyte Interphases

Cited by 81 publications

References 43 publications

Li2CO3/LiF‐Rich Heterostructured Solid Electrolyte Interphase with Superior Lithiophilic and Li+‐Transferred Characteristics via Adjusting Electrolyte Additives

Li2CO3/LiF‐Rich Heterostructured Solid Electrolyte Interphase with Superior Lithiophilic and Li+‐Transferred Characteristics via Adjusting Electrolyte Additives

Guiding Fabrication of Continuous Carbon-Confined Sb2Se3 Nanoparticle Structure for Durable Potassium-Storage Performance

Unveiling the Role of Li+ Solvation Structures with Commercial Carbonates in the Formation of Solid Electrolyte Interphase for Lithium Metal Batteries

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Product

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Hexafluoroisopropyl Trifluoromethanesulfonate‐Driven Easily Li⁺ Desolvated Electrolyte to Afford Li||NCM811 Cells with Efficient Anode/Cathode Electrolyte Interphases

Li₂CO₃/LiF‐Rich Heterostructured Solid Electrolyte Interphase with Superior Lithiophilic and Li⁺‐Transferred Characteristics via Adjusting Electrolyte Additives

Li₂CO₃/LiF‐Rich Heterostructured Solid Electrolyte Interphase with Superior Lithiophilic and Li⁺‐Transferred Characteristics via Adjusting Electrolyte Additives

Guiding Fabrication of Continuous Carbon-Confined Sb₂Se₃ Nanoparticle Structure for Durable Potassium-Storage Performance

Unveiling the Role of Li⁺ Solvation Structures with Commercial Carbonates in the Formation of Solid Electrolyte Interphase for Lithium Metal Batteries