Spectroscopic Insight into Li‐Ion Batteries during Operation: An Alternative Infrared Approach

Corte, Daniel Alves Dalla; Caillon, Georges; Jordy, Christian; Chazalviel, J.‐N.; Rosso, Michel; Ozanam, F.

doi:10.1002/aenm.201501768

Cited by 49 publications

(65 citation statements)

References 94 publications

(196 reference statements)

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“…[19] This twophase picture has been evidenced by microscopic investigations on silicon nanowires. The "hysteresis" behavior during the first cycle has been explained as follows: the gradual increase of the IR absorbance during the first lithiation is consistent with the formation of a heavily lithiated phase progressively invading the silicon layer at a constant (current driven) speed.…”

Section: Lithiation and Delithiation Of Hydrogenated Amorphous Silicomentioning

confidence: 79%

“…[19], the large IR background growing at high energy (i.e., high wavenumbers) is not a Drude-like absorption like in metals and it is not consistent with a light scattering process. [19], the large IR background growing at high energy (i.e., high wavenumbers) is not a Drude-like absorption like in metals and it is not consistent with a light scattering process.…”

Section: Origin Of the Infrared Absorption Of Lithiated A-si:h And A-mentioning

confidence: 90%

“…At low wavenumbers (≈1000-2000 cm −1 ) and as discussed elsewhere, they exhibit several peaks ascribed to the solid electrolyte interphase (SEI) layer and electrolyte absorption. [19], the baseline of the IR spectra gradually increases during the first lithiation, whereas it sharply decreases during the subsequent delithiation. [19], the baseline of the IR spectra gradually increases during the first lithiation, whereas it sharply decreases during the subsequent delithiation.…”

Section: Lithiation and Delithiation Of Hydrogenated Amorphous Silicomentioning

confidence: 95%

“…[19] Operando measurements were carried out with a homemade program for synchronization of the IR measurements with the GCPL measurement. Galvanostatic cycling with potential limitation (GCPL) was performed with a home-made galvanostat.…”

Section: Methodsmentioning

confidence: 99%

“…One way to increase the energy density is to use Li alloys. [19] We use here this approach in which the active material is directly deposited as a homogeneous thin film on the IR window, which makes the observation of changes inside the active material possible while controlling the lithium incorporation. [3] Among these materials, silicon has the highest theoretical specific capacity (3580 mA h g −1 for Li 3.75 Si).…”

Section: Introductionmentioning

confidence: 99%

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Lithiation Mechanism of Methylated Amorphous Silicon Unveiled by Operando ATR‐FTIR Spectroscopy

Koo

Corte

Chazalviel

et al. 2018

Advanced Energy Materials

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The lithiation mechanism of methylated amorphous silicon, a‐Si1−x(CH3)x:H, with various methyl contents (x = 0 ‐ 0.12) is investigated using operando attenuated total reflection Fourier transform infrared spectroscopy. As in hydrogenated amorphous silicon, a‐Si:H, the first lithiation proceeds via a two‐phase mechanism. The concentration of the invading Li‐rich phase nonmonotonously depends on the methyl content of the active material. This behavior is tentatively explained by two distinct effects: a softening of the material due to a methyl‐induced lowering of its reticulation degree and its cohesion, and the presence of nanovoids at high enough methyl content.

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Section: Lithiation and Delithiation Of Hydrogenated Amorphous Silicomentioning

confidence: 79%

Section: Origin Of the Infrared Absorption Of Lithiated A-si:h And A-mentioning

confidence: 90%

Section: Lithiation and Delithiation Of Hydrogenated Amorphous Silicomentioning

confidence: 95%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Lithiation Mechanism of Methylated Amorphous Silicon Unveiled by Operando ATR‐FTIR Spectroscopy

Koo

Corte

Chazalviel

et al. 2018

Advanced Energy Materials

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Silicon Solid State Battery: The Solid‐State Compatibility, Particle Size, and Carbon Compositing for High Energy Density

Boorboor Ajdari,

Asghari,

Molaei Aghdam

et al. 2024

Adv Funct Materials

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Solid‐state battery research has gained significant attention due to their inherent safety and high energy density. Silicon anodes have been promoted for their advantageous characteristics, including high volumetric capacity, low lithiation potential, high theoretical and specific gravimetric capacity, and the absence of lethal dendritic growth. Addressing concerns such as low conductivity, pulverization, fracture, dense solid electrolyte interface layer, and low coulombic efficiency has substantially improved the use of silicon electrodes in solid‐state batteries. Researchers have explored carbon additions, solid electrolyte suitability for Si anodes, pressure optimization, and particle size effects (nano/micro) to enhance energy density. Recent studies have investigated the conductivity mechanism, stack pressure, and anode‐solid electrolyte compatibility to improve energy density. Micro‐ and nano‐sized silicon have attracted attention in carbon‐based composites due to their exceptional conductivity, uniform distribution, efficient electron migration, and diffusion channels. The development of solid‐state batteries with high energy density, safety, and extended lifespan has been a major focus. This review sheds light on significant insights and strategic approaches for researchers working on solid‐state silicon‐based systems to overcome existing challenges.

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Review of Recent Development of In Situ/Operando Characterization Techniques for Lithium Battery Research

et al. 2019

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The increasing demands of energy storage require the significant improvement of current Li-ion battery electrode materials and the development of advanced electrode materials. Thus, it is necessary to gain an in-depth understanding of the reaction processes, degradation mechanism, and thermal decomposition mechanisms of electrode materials under realistic operation conditions. This understanding can be obtained by in situ/operando characterization techniques that provide information on the structure evolution, redox mechanism, solid-electrolyte interphase (SEI) formation, side reactions and Li-ion transport properties under operating conditions. Here, the recent developments in the in situ/operando techniques employed for the investigation of the structural stability, dynamic properties, chemical environment changes and morphological evolution during electrochemical processes are described and summarized in detail. The experimental approaches reviewed in this paper include X-ray, electron, neutron, optical, and scanning probes. Each advanced technique has unique capabilities to study specific properties of electrode materials within specific limitations. The experimental methods and operating principles, especially the in situ cell designs, are described in detail. To illustrate the applicability and uniqueness of each technique, representative studies making use of the in situ/operando techniques are discussed and summarized. Finally, the major current challenges and future opportunities of the in situ/operando techniques are discussed. Several important battery challenges are likely to benefit from these in situ/operando techniques, including the inhomogeneous reactions of This article is protected by copyright. All rights reserved. 4high energy density cathodes, the development of safe and reversible Li metal plating and the development of stable SEI on electrodes.Received: ((will be filled in by the editorial staff))Revised: ((will be filled in by the editorial staff))

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Spectroscopic Insight into Li‐Ion Batteries during Operation: An Alternative Infrared Approach

Cited by 49 publications

References 94 publications

Lithiation Mechanism of Methylated Amorphous Silicon Unveiled by Operando ATR‐FTIR Spectroscopy

Lithiation Mechanism of Methylated Amorphous Silicon Unveiled by Operando ATR‐FTIR Spectroscopy

Silicon Solid State Battery: The Solid‐State Compatibility, Particle Size, and Carbon Compositing for High Energy Density

Review of Recent Development of In Situ/Operando Characterization Techniques for Lithium Battery Research

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