Three-Dimensional Mapping of Resistivity and Microstructure of Composite Electrodes for Lithium-Ion Batteries

Stetson, Caleb; Huey, Zoey; Downard, Ali; Li, Zhifei; To, Bobby; Zakutayev, Andriy; Jiang, Chun‐Sheng; Al‐Jassim, Mowafak; Finegan, Donal P.; Han, Sang‐Don; DeCaluwe, Steven C.

doi:10.1021/acs.nanolett.0c03074

Cited by 9 publications

(10 citation statements)

References 48 publications

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“…Finally, for exploring the spatial electrical properties of electrode materials, scanning spreading resistance microscopy (SSRM) has been applied to measure the resistivity of surface layers on electrodes in 3D with spatial resolution of nanometers for fields of view of 10s of micrometers (Figure 3) [43,44] and holds great potential for understanding the influence of different operating conditions, formation conditions, electrolyte additives, and electrode materials on the thickness and electrical resistivity of surface layers on electrodes, thus providing valuable impedance information for modeling techniques. These heterogeneities at the electrode and particle scales incur consequences for the operation of cells and must be reflected in modeling methods to achieve a high degree of accuracy and be able to predict degradation and optimal operating conditions.…”

Section: Laboratory-based Techniquesmentioning

confidence: 99%

Guiding the Design of Heterogeneous Electrode Microstructures for Li‐Ion Batteries: Microscopic Imaging, Predictive Modeling, and Machine Learning

Zhu

Finegan

et al. 2021

Advanced Energy Materials

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Electrochemical and mechanical properties of lithium‐ion battery materials are heavily dependent on their 3D microstructure characteristics. A quantitative understanding of the role played by stochastic microstructures is critical for the prediction of material properties and for guiding synthesis processes. Furthermore, tailoring microstructure morphology is also a viable way of achieving optimal electrochemical and mechanical performances of lithium‐ion cells. To facilitate the establishment of microstructure‐resolved modeling and design methods, a review covering spatially and temporally resolved imaging of microstructure and electrochemical phenomena, microstructure statistical characterization and stochastic reconstruction, microstructure‐resolved modeling for property prediction, and machine learning for microstructure design is presented here. The perspectives on the unresolved challenges and opportunities in applying experimental data, modeling, and machine learning to improve the understanding of materials and identify paths toward enhanced performance of lithium‐ion cells are presented.

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Section: Laboratory-based Techniquesmentioning

confidence: 99%

Guiding the Design of Heterogeneous Electrode Microstructures for Li‐Ion Batteries: Microscopic Imaging, Predictive Modeling, and Machine Learning

Zhu

Finegan

et al. 2021

Advanced Energy Materials

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“…[ 39 ] Closely related techniques have utilized various input/detection arrangements to provide high‐resolution contrast in the electronic properties (resistivity mapping) of electrode components which, for example, can enable different materials to be distinguished. [ 40 ]…”

Section: Technical Background: Ec‐afm and Libsmentioning

confidence: 99%

Characterizing Batteries by In Situ Electrochemical Atomic Force Microscopy: A Critical Review

Zhang

Said

Smith

et al. 2021

Advanced Energy Materials

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Although lithium, and other alkali ion, batteries are widely utilized and studied, many of the chemical and mechanical processes that underpin the materials within, and drive their degradation/failure, are not fully understood. Hence, to enhance the understanding of these processes various ex situ, in situ and operando characterization methods are being explored. Recently, electrochemical atomic force microscopy (EC‐AFM), and related techniques, have emerged as crucial platforms for the versatile characterization of battery material surfaces. They have revealed insights into the morphological, mechanical, chemical, and physical properties of battery materials when they evolve under electrochemical control. This critical review will appraise the progress made in the understanding batteries using EC‐AFM, covering both traditional and new electrode–electrolyte material junctions. This progress will be juxtaposed against the ability, or inability, of the system adopted to embody a truly representative battery environment. By contrasting key EC‐AFM literature with conclusions drawn from alternative characterization tools, the unique power of EC‐AFM to elucidate processes at battery interfaces is highlighted. Simultaneously opportunities for complementing EC‐AFM data with a range of spectroscopic, microscopic, and diffraction techniques to overcome its limitations are described, thus facilitating improved battery performance.

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“…These changes result in electrode thickness variations [14], loss of electrical particle contact within the microstructure [15,16], continued consumption of electrolyte [17], all of which affects the electrode's electrochemical performance [18]. All those phenomena depend on the exact particles location along the electrode, where the heterogeneous distribution of electrode components in 3D becomes important when trying to understand the coupled mechanical and electrochemical behavior of graphite/Si composite electrodes [19,20]. Experimental 3D probing techniques, such as X-ray tomography [19], or the more recently developed scanning spreading resistance microscopy (SSRC) [20], are critical when trying to extract fundamental insights about the microstructure-performance relationships of battery electrodes in general, and of graphite/Si composite in particular.…”

Section: Introductionmentioning

confidence: 99%

“…All those phenomena depend on the exact particles location along the electrode, where the heterogeneous distribution of electrode components in 3D becomes important when trying to understand the coupled mechanical and electrochemical behavior of graphite/Si composite electrodes [19,20]. Experimental 3D probing techniques, such as X-ray tomography [19], or the more recently developed scanning spreading resistance microscopy (SSRC) [20], are critical when trying to extract fundamental insights about the microstructure-performance relationships of battery electrodes in general, and of graphite/Si composite in particular. However, those techniques are too costly to be used systematically, and often require not routinely accessible instrumentations, such as synchrotron beamlines.…”

Section: Introductionmentioning

confidence: 99%

“…However, those techniques are too costly to be used systematically, and often require not routinely accessible instrumentations, such as synchrotron beamlines. In addition, those techniques often need to find compromises between the appropriate resolution/phase contrast needed to resolve certain phases, such as the carbon binder domain (CBD) [21,22], and the sample size, which can hinder microstructural representativity [20].…”

Section: Introductionmentioning

confidence: 99%

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Towards a 3D-resolved model of Si/Graphite composite electrodes from manufacturing simulations

Liu

Arcelus

Lombardo

et al. 2021

Preprint

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Composite graphite/silicon (Si) electrodes with low Si weight percentages are considered as a promising anode for next generation Li-ion batteries. In this context, understanding the microstructural changes due to Si volume expansion and the complex electrochemical interplay between graphite and Si becomes crucial to unlock real-life applications of such composite electrodes. This work presents a three-dimensional (3D) physics-based model coupling electrochemistry and mechanics, using as input electrode microstructures obtained from manufacturing-related Coarse-Grained Molecular Dynamics models. The slurry and dried electrode microstructure are first generated by considering graphite and additives only, while the Si is included in an additional step. The model herein presented is a step further into obtaining a fundamental understanding of the complex processes happening in graphite/Si composite electrodes, paving the way towards their optimization.

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Three-Dimensional Mapping of Resistivity and Microstructure of Composite Electrodes for Lithium-Ion Batteries

Cited by 9 publications

References 48 publications

Guiding the Design of Heterogeneous Electrode Microstructures for Li‐Ion Batteries: Microscopic Imaging, Predictive Modeling, and Machine Learning

Guiding the Design of Heterogeneous Electrode Microstructures for Li‐Ion Batteries: Microscopic Imaging, Predictive Modeling, and Machine Learning

Characterizing Batteries by In Situ Electrochemical Atomic Force Microscopy: A Critical Review

Towards a 3D-resolved model of Si/Graphite composite electrodes from manufacturing simulations

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