Silicon Nanoparticles with a Polymer-Derived Carbon Shell for Improved Lithium-Ion Batteries: Investigation into Volume Expansion, Gas Evolution, and Particle Fracture

Schiele, Alexander; Breitung, Ben; Mazilkin, Andrey; Schweidler, Simon; Janek, Jürgen; Gumbel, Simon; Fleischmann, Sven; Burakowska-Meise, Ewelina; Sommer, Heino; Brezesinski, Torsten

doi:10.1021/acsomega.8b02541

Cited by 35 publications

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References 44 publications

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“…A custom setup for highthroughput in situ pressure analysis was demonstrated by Schiele et al [102] and is shown in Figure 12a. In fact, in situ pressure measurements have been performed on some anode and cathode materials in the past [102,103,212,213] (on an electrode level) to gain insights into 3D volume changes of practical electrodes. To probe the "true" gas evolution with cycling, usually the cell volume is determined first.…”

Section: In Situ Gas Analyticsmentioning

confidence: 99%

Chemical, Structural, and Electronic Aspects of Formation and Degradation Behavior on Different Length Scales of Ni‐Rich NCM and Li‐Rich HE‐NCM Cathode Materials in Li‐Ion Batteries

et al. 2019

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costs are required. Current state-of-theart LIBs using, e.g., well-established LiNi 1/3 Co 1/3 Mn 1/3 O 2 (NCM111) cathode material are yet not able to fulfill all these demands. In order to increase the energy density of LIBs, battery produ cers and researchers pursue various strategies. Substitution of expensive Co by Ni to achieve LiNi 1−x−y Co x Mn y O 2 compounds with x < 0.3 in order to increase the structural stability at high state-of-charge (SOC) is one possible approach. Another promising material class is represented by Li-rich high-energy NCM (HE-NCM) materials (cLi 2 MnO 3 ⋅[1 − c]LiTMO 2 [TM = Ni, Co, Mn, etc.]). All of these subgroups of layered oxides have in common a crystal structure that is prone to irreversible changes and fatigue during continuous Li (de-)intercalation. The relevant changes in electronic and crystal structure strongly depend on the particular cathode composition and micro/nanostructure. The development of a target-oriented roadmap to improved LIBs that meet the above requirements must address the underlying mechanisms on different cell levels, i.e., from the atomic level to the electrode level. A comprehensive summary of the properties and developments in the field of Ni-rich NCM [1][2][3][4][5][6][7][8][9] and Li-rich HE-NCM [10][11][12][13][14][15][16] has been presented recently In order to satisfy the energy demands of the electromobility market, both Ni-rich and Li-rich layered oxides of NCM type are receiving much attention as high-energy-density cathode materials for application in Li-ion batteries. However, due to different stability issues, their longevity is limited. During formation and continuous cycling, especially the electronic and crystal structure suffers from various changes, eventually leading to fatigue and mechanical degradation. In recent years, comprehensive battery research has been conducted at Karlsruhe Institute of Technology, mainly aiming at better understanding the primary degradation processes occurring in these layered transition metal oxides. The characteristic process of formation and mechanisms of fatigue are fundamentally characterized and the effect of chemical composition on cell chemistry, electrochemistry, and cycling stability is addressed on different length scales by use of state-of-the-art analytical techniques, ranging from "standard" characterization tools to combinations of advanced in situ and operando methods. Here, the results are presented and discussed within a broader scientific context. by several authors. Here, we focus on the detailed characterization of these materials on different length scales, including the processes during formation and fatigue.After a brief introduction of the different materials addressed here, their characteristic process of formation and mechanisms of fatigue are discussed with respect to cell chemistry, electrochemistry, and cycling stability. Based on the fundamental results of our experimental studies on the material level, the effect of formation and fatigue on different cell levels is evalu...

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Section: In Situ Gas Analyticsmentioning

confidence: 99%

Chemical, Structural, and Electronic Aspects of Formation and Degradation Behavior on Different Length Scales of Ni‐Rich NCM and Li‐Rich HE‐NCM Cathode Materials in Li‐Ion Batteries

et al. 2019

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“…[52][53][54] Ad etailedd escription of the setup used and the general working principle can be found in Ref. This methodw as already used to monitorL ip lating/stripping and the volume expansion/contraction of graphite and silicon anodes.…”

Section: Pressureanalysismentioning

confidence: 99%

“…This methodw as already used to monitorL ip lating/stripping and the volume expansion/contraction of graphite and silicon anodes. [52][53][54] Ad etailedd escription of the setup used and the general working principle can be found in Ref. [52,54] as well as in Appendix SI 1a nd Figure S4.…”

Section: Pressureanalysismentioning

confidence: 99%

Phase Transformation Behavior and Stability of LiNiO₂ Cathode Material for Li‐Ion Batteries Obtained from In Situ Gas Analysis and Operando X‐Ray Diffraction

et al. 2019

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“…The mass increase starting between 500 and 600°C can be assigned to SiO x formation in case of Si nanoparticles. [15] Since this SiO x formation appears in the case of Si/C composites after decomposition of the carbon shell as well, the mass difference at 800°C between both measure-ments is related to the total amount of carbon burnt. The mass increase at a later stage of Si and Si/C nanopowders can be ascribed to the formation of SiO 2 due to oxidation of silicon.…”

Section: Resultsmentioning

confidence: 99%

Tailored Silicon/Carbon Compounds for Printed Li–Ion Anodes

Sukkurji

Issac

Singaraju

et al. 2020

Batteries & Supercaps

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Silicon (Si) has turned out to be a promising active material for next-generation lithium-ion battery anodes. Nevertheless, the issues known from Si as electrode material (pulverization effects, volume change etc.) are impeding the development of Si anodes to reach market maturity. In this study, we are investigating a possible application of Si anodes in low-power printed electronic applications. Tailored Si inks are produced and the impact of carbon coating on the printability and their electrochemical behavior as printed Si anodes is investigated. The printed Si anodes contain active material loadings that are practical for powering printed electronic devices, like electrolyte gated transistors, and are able to show high capacity retentions. A capacity of 1754 mAh/g Si is achieved for a printed Si anode after 100 cycles. Additionally, the direct applicability of the printed Si anodes is shown by successfully powering an ink-jet printed transistor.

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Silicon Nanoparticles with a Polymer-Derived Carbon Shell for Improved Lithium-Ion Batteries: Investigation into Volume Expansion, Gas Evolution, and Particle Fracture

Cited by 35 publications

References 44 publications

Chemical, Structural, and Electronic Aspects of Formation and Degradation Behavior on Different Length Scales of Ni‐Rich NCM and Li‐Rich HE‐NCM Cathode Materials in Li‐Ion Batteries

Chemical, Structural, and Electronic Aspects of Formation and Degradation Behavior on Different Length Scales of Ni‐Rich NCM and Li‐Rich HE‐NCM Cathode Materials in Li‐Ion Batteries

Phase Transformation Behavior and Stability of LiNiO₂ Cathode Material for Li‐Ion Batteries Obtained from In Situ Gas Analysis and Operando X‐Ray Diffraction

Tailored Silicon/Carbon Compounds for Printed Li–Ion Anodes

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Silicon Nanoparticles with a Polymer-Derived Carbon Shell for Improved Lithium-Ion Batteries: Investigation into Volume Expansion, Gas Evolution, and Particle Fracture

Cited by 35 publications

References 44 publications

Chemical, Structural, and Electronic Aspects of Formation and Degradation Behavior on Different Length Scales of Ni‐Rich NCM and Li‐Rich HE‐NCM Cathode Materials in Li‐Ion Batteries

Chemical, Structural, and Electronic Aspects of Formation and Degradation Behavior on Different Length Scales of Ni‐Rich NCM and Li‐Rich HE‐NCM Cathode Materials in Li‐Ion Batteries

Phase Transformation Behavior and Stability of LiNiO2 Cathode Material for Li‐Ion Batteries Obtained from In Situ Gas Analysis and Operando X‐Ray Diffraction

Tailored Silicon/Carbon Compounds for Printed Li–Ion Anodes

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Phase Transformation Behavior and Stability of LiNiO₂ Cathode Material for Li‐Ion Batteries Obtained from In Situ Gas Analysis and Operando X‐Ray Diffraction