Li<sub>15</sub>Si<sub>4</sub>Formation in Silicon Thin Film Negative Electrodes

Iaboni, Douglas S.M.; Obrovac, M. N.

doi:10.1149/2.0551602jes

Cited by 120 publications

(167 citation statements)

References 25 publications

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“…[25][26] No plateau related to Li 15 Si 4 is present during these initial cycles, which is consistent with Si films where Li 15 Si 4 formation can be suppressed by the stress between the Si film and the substrate. 27 With increasing B concentration, both sloping plateaus shorten gradually so that the reversible capacity of Si 1-x B x electrode decreases. Nevertheless, Si 1-x B x electrodes with more than 80 at% B content still show obvious lithium storage capability.…”

Section: Resultsmentioning

confidence: 95%

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The Electrochemistry of Amorphous Si-B Thin Film Electrodes in Li Cells

Liu

Zhu

et al. 2015

J. Electrochem. Soc.

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Si1-xBx thin films of 0.071 ≤ x ≤ 0.950 have been synthesized using combinational sputtering. All Si1-xBx film compositions had a highly amorphous structure consisting of amorphous Si and B phases, as characterized by X-ray diffraction. In Li cells, it was found that all of the Si is active and the B is inactive with lithium. Otherwise, the Si1-xBx films have similar characteristics as pure Si film electrodes in Li cells, except with reduced capacity due to the added B. However, shifts in the voltage curves appear when the B content is increased that may be induced by stress-voltage coupling between the active Si and the inactive B phases.

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Section: Resultsmentioning

confidence: 95%

“…A weakly bonded Si active phase has been shown to result in Li 15 Si 4 formation and fade during cycling in thin films. 27 We will explore the longer-term cycling implications of this potentially weak interaction in a later publication using Si-B made by mechanical milling.…”

Section: Resultsmentioning

confidence: 99%

The Electrochemistry of Amorphous Si-B Thin Film Electrodes in Li Cells

Liu

Zhu

et al. 2015

J. Electrochem. Soc.

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“…[22] Another possiblee xplanation is ab uffering effect of the porous shell that hinders the volume expansion of the SiNW to some extent.L i 15 Si 4 cannoto ccur when the lithiation induced stresses suppress the electrochemical potential. [33] The porous shell prevents the expansion of the SiNW and the induced stress lowers the formation potential of Li 15 Si 4 .…”

Section: Electrochemical Behavior Of Porous and Nonporous Sinwmentioning

confidence: 99%

Lithiation Behavior of Silicon Nanowire Anodes for Lithium‐Ion Batteries: Impact of Functionalization and Porosity

et al. 2017

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Metal‐assisted chemical etching (MACE) provides a versatile way to synthesize silicon nanowires (SiNW) of different morphologies. MACE was used to synthesize oxide‐free porous and nonporous SiNW for use as anodes for lithium‐ion batteries. To improve their processing behavior, the SiNW were functionalized using acrylic acid. Differential capacity plots were used as a way to identify the degradation processes during cycling through tracking the formation of Li15Si4 and changes in polarization. The cycling performance between porous and nonporous SiNW differed regarding Coulombic efficiency and cycling stability. The differences were attributed to the porous hull and its ability to reduce the volume expansion, although not through its porous nature but the reduced uptake of Li ions.

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“…1,2 In contrast to conventional intercalation anode materials, such as graphite (LiC 6 , 372 mAh g −1 , 890 Ah L −1 ), the specific capacity of silicon alloy electrodes is significantly higher (Li 15 Si 4 , 3579 mAh g −1 , 2194 Ah L −1 ). 3 Nonetheless, commercialization of silicon-based electrodes is still hampered because of two major challenges: 4 (i) Large volume expansions up to 280% upon repeated (de-)lithiation of silicon particles deteriorate the electrode integrity, thus causing isolation of active material.…”

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“…While these conditions would also be satisfied by a lithium metal electrode, the third reason is (iii) to minimize side reactions of the electrolyte at the positive electrode (here: LiFePO 4 ), which would alter the electrolyte (and FEC) decomposition and thus influence its quantification. As electrolyte we use 1 M LiPF 6 in EC:EMC (LP57) with 5 wt% of the widely used fluoroethylene carbonate (FEC) as additive, which is known to significantly improve the cycling stability of the silicon-graphite electrode. 32 We also added a comparably large amount of electrolyte to the coin cells (130 μL or 84 μL cm −2 ; ∼15 times larger compared to large-scale cells), because it allows for a more precise quantification of the FEC consumption via 19 F-NMR.…”

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Differentiating the Degradation Phenomena in Silicon-Graphite Electrodes for Lithium-Ion Batteries

Wetjen

Pritzl

Jung

et al. 2017

J. Electrochem. Soc.

145

173

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Silicon-graphite electrodes usually experience an increase in cycling performance by the addition of graphite, however, the relation of the silicon/graphite ratio and the aging mechanisms of the individual electrode and electrolyte compounds still requires a more fundamental understanding. In this study, we present a comprehensive approach to understand and quantify the degradation phenomena in silicon-graphite electrodes with silicon contents between 20-60 wt%. By evaluating the cycling performance and total irreversible capacity of silicon-graphite electrodes vs. capacitively oversized LiFePO 4 electrodes in presence of a fluoroethylene carbonate (FEC)-containing electrolyte, we demonstrate that the aging of silicon-based electrodes can be distinguished into two distinct phenomena, which we describe as silicon particle degradation and electrode degradation. Cross-sectional scanning electron microscopy (SEM) images and a detailed analysis of the electrode polarization upon cycling complement our discussion. Further, we deploy post-mortem 19 F-NMR spectroscopy to (i) quantify to loss of moles of FEC in the electrolyte and correlate this with the amount of charge that was exchanged by the silicon-graphite electrodes, (ii) estimate the pore volume of the silicon-graphite electrodes that is occupied by FEC decomposition products, and (iii) Silicon-based electrodes are very promising candidates to enable the next generation of Li-ion batteries with energy densities on the cell level beyond 350 Wh kg −1 . 1,2 In contrast to conventional intercalation anode materials, such as graphite (LiC 6 , 372 mAh g −1 , 890 Ah L −1 ), the specific capacity of silicon alloy electrodes is significantly higher (Li 15 Si 4 , 3579 mAh g −1 , 2194 Ah L −1 ). 3 Nonetheless, commercialization of silicon-based electrodes is still hampered because of two major challenges: 4 (i) Large volume expansions up to 280% upon repeated (de-)lithiation of silicon particles deteriorate the electrode integrity, thus causing isolation of active material. [5][6][7] The formerly reported pulverization of micron-sized silicon particles due to mechanical stress upon repeated volume expansion has been partially solved by using nanometer-sized particles. However, reduction of the silicon particle size also leads to inferior electronic conduction due to more numerous interparticle contacts, and higher solid-electrolyte-interphase (SEI) losses due to the larger relative surface area. [8][9][10] (ii) Continuous side reactions at the silicon/electrolyte interface caused by repeated volume expansion and contraction result in ongoing electrolyte decomposition and in a gradual loss of active lithium. 8In the course of this, SEI-forming additives in the electrolyte, e.g., FEC, are depleted, which was shown to result in a significant increase in cell polarization and a concomitant rapid capacity drop. 8,11 Various strategies have been proposed to overcome the detrimental effects associated with the volume expansion during (de-)lithiation of silicon and to reduce conc...

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Li₁₅Si₄Formation in Silicon Thin Film Negative Electrodes

Cited by 120 publications

References 25 publications

The Electrochemistry of Amorphous Si-B Thin Film Electrodes in Li Cells

The Electrochemistry of Amorphous Si-B Thin Film Electrodes in Li Cells

Lithiation Behavior of Silicon Nanowire Anodes for Lithium‐Ion Batteries: Impact of Functionalization and Porosity

Differentiating the Degradation Phenomena in Silicon-Graphite Electrodes for Lithium-Ion Batteries

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Li15Si4Formation in Silicon Thin Film Negative Electrodes

Cited by 120 publications

References 25 publications

The Electrochemistry of Amorphous Si-B Thin Film Electrodes in Li Cells

The Electrochemistry of Amorphous Si-B Thin Film Electrodes in Li Cells

Lithiation Behavior of Silicon Nanowire Anodes for Lithium‐Ion Batteries: Impact of Functionalization and Porosity

Differentiating the Degradation Phenomena in Silicon-Graphite Electrodes for Lithium-Ion Batteries

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Li₁₅Si₄Formation in Silicon Thin Film Negative Electrodes