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ข้อมูลเชิงลึก - Battery Technology - # Chemo-mechanical modelling in battery research and development

Chemo-Mechanical Modelling: A Critical Tool for Advancing Battery Technology


แนวคิดหลัก
Chemo-mechanical modelling is a crucial tool for understanding and improving the performance and lifetime of current and next-generation battery technologies, addressing key challenges such as diffusion-induced stress, volumetric strains, and dendrite growth.
บทคัดย่อ

The content provides an overview and perspective on the role of chemo-mechanical modelling in the development of battery technology. It highlights the importance of considering solid mechanics, in addition to electrochemistry, transport, and thermodynamics, to fully understand the complex operating mechanisms of batteries.

The key points are:

  • Diffusion-induced stress and volumetric strains in active materials, as well as the initiation and growth of voids and lithium dendrites, are critical issues that can lead to battery degradation and failure. Chemo-mechanical modelling is essential for addressing these challenges.
  • The content outlines the fundamental equations that link electrochemistry and mechanics, and discusses the importance of appropriate constitutive formulations, fracture modelling, and material property measurements in chemo-mechanical models.
  • Chemo-mechanical models are developed at multiple scales, from single particles to entire electrodes, to provide insights into the complex deformation and failure mechanisms in batteries.
  • Continued interdisciplinary collaboration and the integration of computational modelling and experimental validation are crucial for advancing chemo-mechanical research and its application in battery technology.
  • The increasing focus on solid-state batteries requires significant attention to chemo-mechanical phenomena, such as pulverization of alloy anodes, dendrite growth, and interfacial contact loss, which must be addressed through chemo-mechanical modelling and experiments.
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สถิติ
Lithiation-induced strain, ε_L, is typically given by the expression: ε_L = 1/3 Ω(c-c_0)I, where Ω is the partial molar volume, c is the lithium concentration, c_0 is the initial lithium concentration, and I is the identity tensor. The chemical potential, μ, is affected by the hydrostatic stress, σ_H, according to the equation: μ = μ_0 + RT ln(c/(c_max-c)) - Ω σ_H. The diffusive flux, J, of lithium in the active materials is also affected by the hydrostatic stress, as shown by the equation: J = -D(∇c - Ω c/(RT)∇σ_H), where D is the diffusion coefficient.
คำพูด
"If diffusion-induced stresses and volumetric straining occurs during operation, battery capacity can be directly affected by increasing or decreasing the overpotentials, since overpotential is related directly to the electrochemical potential." "Fracture plays a central role in the long-term stability of battery materials, and it is crucial that it is considered from a modelling perspective." "Technological development of battery systems requires the intersection of computational modelling and experiment; experiments fulfil the crucial role of physical insight, while also providing the basis for computational models that provide a cost-effective way of design and optimisation as well as enabling further physical insight."

ข้อมูลเชิงลึกที่สำคัญจาก

by A. B... ที่ arxiv.org 03-29-2024

https://arxiv.org/pdf/2403.19244.pdf
The role of chemo-mechanical modelling in the development of battery  technology -- a perspective

สอบถามเพิ่มเติม

How can chemo-mechanical modelling be integrated into battery management systems to enable rapid electrode or cell design and optimization?

Chemo-mechanical modelling can be integrated into battery management systems by developing computational models that simulate the electrochemical, transport, and mechanical processes within batteries. These models can provide insights into the behavior of batteries under different operating conditions, allowing for the optimization of electrode and cell designs. By incorporating chemo-mechanical models into battery management systems, researchers and engineers can predict the performance and degradation mechanisms of batteries more accurately. This integration enables rapid prototyping and testing of new electrode materials and architectures, leading to the development of more efficient and durable battery systems.

What are the key challenges in accurately measuring material properties at the micro- and nano-scales, and how can these be addressed to improve the predictive capabilities of chemo-mechanical models?

Accurately measuring material properties at the micro- and nano-scales poses several challenges, including the difficulty of obtaining representative samples, the influence of concentration-dependent properties, and the need for repeatable measurements. To address these challenges and improve the predictive capabilities of chemo-mechanical models, researchers can employ advanced characterization techniques such as electron microscopy, atomic force microscopy, and X-ray diffraction. These techniques allow for the precise measurement of material properties at small scales and provide valuable data for model parameterization. Additionally, establishing standardized testing protocols and ensuring experimental repeatability are essential for generating reliable material property data that can be used in chemo-mechanical models.

How can chemo-mechanical modelling be leveraged to guide the development of novel battery materials and architectures that can overcome the limitations of current technologies, such as the large volume changes and dendrite growth in lithium-based systems?

Chemo-mechanical modelling can guide the development of novel battery materials and architectures by predicting the mechanical response of new materials to electrochemical processes. By simulating the behavior of batteries at the micro- and nano-scales, researchers can identify potential failure mechanisms, such as large volume changes and dendrite growth, and design strategies to mitigate these issues. Chemo-mechanical models can be used to optimize the composition, structure, and processing of battery materials to enhance their mechanical stability and electrochemical performance. By leveraging these models, researchers can accelerate the discovery and development of advanced battery technologies that address the limitations of current systems and pave the way for more efficient and reliable energy storage solutions.
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