Characterizing Solid Electrolyte Interphase on Sn Anode in Lithium Ion Battery

Seo, Daniel M.; Nguyen, Cao Cuong; Young, Benjamin; Heskett, David R.; Woicik, J. C.; Lucht, Brett L.

doi:10.1149/2.0121513jes

Cited by 46 publications

(76 citation statements)

References 27 publications

(52 reference statements)

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“…[33] The proportion of C-C(H) peak at 285 eV increases prominently after long cycling: an indication of the formation of sodium alkoxides (RCH 2 ONa) groups as a result of reduction of DGME. [34] Note also the appearance of another peak at 290 eV corresponding to the formation of Na 2 CO 3 .…”

Section: Submitted To 4mentioning

confidence: 99%

Microsized Sn as Advanced Anodes in Glyme‐Based Electrolyte for Na‐Ion Batteries

et al. 2016

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Section: Submitted To 4mentioning

confidence: 99%

Microsized Sn as Advanced Anodes in Glyme‐Based Electrolyte for Na‐Ion Batteries

et al. 2016

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“…While once the SEI layer forms by FEC, the SEI is hold at a limited thickness by inhibition of further electrolyte decomposition, with EC the SEI seems to thicken by a continuous electrolyte decomposition with cycling, which is similar phenomenon to the case of silicon . This phenomena and performance fade significantly intensified on bulk Sn‐based anode …”

Section: Resultsmentioning

confidence: 95%

“…Surface degradation can also occur by the dissolution of surface oxide by HF. The most explored approaches to improve the interfacial (SEI) stability have been the use of electrolyte additives, such as phosphite and fluoroethylene carbonate (FEC) but just few studies have focused on investigating the SEI formation on Sn‐based anode . Despite some improvement, challenges in the improvement of performance and SEI stability still remain.…”

Section: Introductionmentioning

confidence: 99%

“…Carbon‐ and polymeric binder‐free film model electrodes deposited on electronically conductive substrate, which otherwise are necessary for porous bulk electrodes, generally possess a strong adherence to the substrate and a robust structure, and can provide high‐quality spectroscopic signals and a precise characterization of the SEI composition, which gives clear insights into electrode–electrolyte interfacial processes and reaction mechanisms, and failure mechanisms . Our earlier works on Sn‐ and silicon‐based film model electrodes suggested that a fundamental understanding of the mechanisms for interfacial reaction and the SEI formation helped find a path towards the SEI stabilization and performance improvement of porous bulk electrode materials . In the past study, we observed that doping of a small fraction of fluorine (F) to Sn–Ni film electrode induced the positive charge on the electrode surface, which behaved as an F anion‐capturing agent from HF inhibiting a direct HF‐attack, and as a resistor against PF 5 and PF 3 O Lewis acids .…”

Section: Introductionmentioning

confidence: 99%

“…FEC has been widely used as an SEI forming agent for alloy anode, mostly silicon . It was recently demonstrated that FEC is an efficient alternative solvent to EC of the conventional electrolyte, enhancing the cycling performance of Sn‐ and silicon‐based anodes . However, reaction mechanisms such as at what voltage and how FEC reduction begins and proceeds, consequently how the SEI layer forms at the surface of Sn‐based anode, and why FEC‐derived SEI is stable remain not understood.…”

Section: Introductionmentioning

confidence: 99%

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Mechanisms for Stable Solid Electrolyte Interphase Formation and Improved Cycling Stability of Tin‐Based Battery Anode in Fluoroethylene Carbonate‐Containing Electrolyte

Hong

Choo

Kwon³

et al. 2016

Adv Materials Inter

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that enable to form a stable solid electrolyte interphase (SEI) layer at the surface of the alternative anode for reliable battery performance. Tin (Sn)-based anode material based on alloy formation with Li has been one of the promising candidates because of the large theoretical capacity (≈992 mAhg −1 ) of Sn compared to that of graphite (372 mAhg −1 ). Sn also holds its merits of appropriate operating voltage above Li, which prevents dendrite formation, and high electronic conductivity as metallic, and improved Li + -transport kinetics. [1][2][3][4] The Sn, however, suffers from a rapid performance fade due to large volume change (≈300%) upon repeated charge (lithiation)-discharge (delithiation) cycling, which results in mechanical and electrical disintegration (i.e., particle cracking) between Sn particles and between the particles and current collector. [1][2][3][4] Several strategies were explored to reduce or accommodate the volume change by mostly adding various carbon (e.g., graphite) and inactive matrix, [2,5,6] and by using nanostructured Sn-carbon composites [7][8][9][10] or functional binder. [11] Since the particle cracking causes the enlarged interfacial area of Sn particles to electrolyte and continuous electrolyte decomposition at the new surface, the volume change event is closely linked to anode-electrolyte interfacial reactivity and stability. Our earlier reported results showed that interfacial irreversible reaction on Sn and destabilization of SEI layer with cycling are additional origins of a rapid performance fade in the ethylene carbonate (EC)-based conventional electrolyte. [12][13][14] Electrophilic attack of LiPF 6 salt-derived acids of PF 5 and PF 3 O (LiPF 6 → PF 5 + LiF, PF 5 + H 2 O PF 3 O + 2HF) [15,16] to the anode surface were determined to be the cause for interfacial reactivity. Surface degradation can also occur by the dissolution of surface oxide by HF. The most explored approaches to improve the interfacial (SEI) stability have been the use of electrolyte additives, such as phosphite [12,13] and fluoroethylene carbonate (FEC) [17][18][19] but just few studies have focused on investigating the SEI formation on Sn-based anode. [12,13,[19][20][21][22] Despite some improvement, challenges in the improvement of performance and SEI stability still remain. Thus, a fundamental understanding of electrode-electrolyte interfacial phenomena Tin-based anode materials are promising candidates for high-energy density Li-ion batteries. Unstable anode-electrolyte interface is a critical problem that needs to be resolved for these materials. The improvement of solid electrolyte interphase (SEI) stability and cycling stability of fluorine-doped Sn-Ni film electrode is observed by the use of fluoroethylene carbonate (FEC)based electrolyte with respect to ethylene carbonate (EC)-based conventional electrolyte. Mechanisms of FEC-derived SEI formation and stabilization are investigated using state of charge-dependent ex situ attenuated total reflection FTIR combined with X-ray photoelectron spectr...

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Interfaces and Interphases in Batteries: How to Identify and Monitor Them Properly Using Surface Sensitive Characterization Techniques

Villevieille

2022

Adv Materials Inter

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design, characterization, equipment, modelling, artificial intelligence, engineering, etc. [3] The main challenges are quite frequently addressed in the literature, including i) the development of a new electroactive material with higher operating voltage/specific capacity, which would increase the overall energy density of the battery; ii) the safety issues concerning the Li metal counter electrode and its uncontrollable interface, called dendrites; iii) the power density of the system, which merits proper electrode architecture and material design; and iv) the replacement of organic liquid electrolytes that are responsible for certain safety issues such as flammability and decomposition caused by electrochemical stability windows smaller than 4 V. [4] Understanding the underlying reaction mechanisms governing the electrochemical processes is an engaging yet challenging task. This is because of the complexity of battery technology: multiple interactions exist that can concern several length scales, from the mm to the nm scale, including the bulk, the surface, the interphase, and their own interactions between each other. [5,6] Another way to actively ensure the development of better/ safer battery systems is a thorough investigation using several advanced characterization techniques (ideally operando, that is, during battery operation) that can probe multiscale lengths. [7,8] Bulk reactions are typically well-understood and monitored because these processes generally occur on a microscopic scale. Furthermore, several characterization techniques were initially developed to monitor bulk reactions, providing substantial knowledge at the macroscopic scale, such as structural evolution. [9] Surface/interphase/interface investigation is more complex primarily because of the size of the "surface" layer (only a few nanometres) and the "fragility" (mechanical and transient nature) of this layer due to its chemical composition. [10,11] Indeed, the surface layer is mainly composed of organic/polymeric species that can easily "burn" during the investigation. A persistent issue that has not yet been properly addressed in the literature is beam damage, which is one of the most common threats to proper interface/interphase investigation. [8,12] This is because the chemical composition of the layer changes rapidly during beam damage. Moreover, interphase/interface/surface chemistries evolve faster than the time-scale resolution of various applied characterization techniques and are primarily Interfaces, interphases, surfaces, and bulk are the main elements in a battery that require to be monitored and understood to control battery life during cycling and electrochemical ageing. To date, bulk-related processes are generally easier to address in terms of characterization techniques because in-depth investigations of most of these processes can be performed in operando mode (that is, during battery cycling). However, investigations of surfaces, interfaces, and interphases possess some challenges due to the involved nanosize dim...

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Characterizing Solid Electrolyte Interphase on Sn Anode in Lithium Ion Battery

Cited by 46 publications

References 27 publications

Microsized Sn as Advanced Anodes in Glyme‐Based Electrolyte for Na‐Ion Batteries

Microsized Sn as Advanced Anodes in Glyme‐Based Electrolyte for Na‐Ion Batteries

Mechanisms for Stable Solid Electrolyte Interphase Formation and Improved Cycling Stability of Tin‐Based Battery Anode in Fluoroethylene Carbonate‐Containing Electrolyte

Interfaces and Interphases in Batteries: How to Identify and Monitor Them Properly Using Surface Sensitive Characterization Techniques

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