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Energy Focus: Novel method developed to investigate stiffness and mechanical stress in Li-ion batteries

By Boris Dyatkin November 9, 2016

Researchers typically gauge the safety and reliability of batteries by the amount of heat

Energy Focus: Novel method developed to investigate stiffness and mechanical stress in Li-ion batteries
Electrochemical stiffness changes during lithiation of a composite graphite electrode. As lithium ions intercalate into the graphite anode during a multistage process, they influence the mechanical properties of the electrode. The charging process generates unique stage-dependent stress and strain in the graphite-lithium intercalation compound. Credit: Hadi Tavassol, Elizabeth M.C. Jones, Nancy R. Sottos, and Andrew A. Gewirth.
Electrochemical stiffness changes during lithiation of a composite graphite electrode. As lithium ions intercalate into the graphite anode during a multistage process, they influence the mechanical properties of the electrode. The charging process generates unique stage-dependent stress and strain in the graphite-lithium intercalation compound. Credit: Hadi Tavassol, Elizabeth M.C. Jones, Nancy R. Sottos, and Andrew A. Gewirth.

that they evolve and the number of cycles that they can sustain before degrading. In addition, in Li-ion batteries, the ion intercalation charge-discharge process used also induces mechanical stress and strain in the electrode materials. The resulting deformation and delamination may, over time, lead to device failure. Due to the complex, heterogeneous nature of the lithium-ion exchange and the structures of the composite electrode materials used, it has proven challenging to develop effective techniques for assessing the kinetic effects of stress and strain, and correlating them with device charging and discharging.

Now Hadi Tavassol, Elizabeth M.C. Jones, Nancy R. Sottos, and Andrew A. Gewirth of the University of Illinois at Urbana-Champaign (UIUC) have developed a novel approach that assesses in situ electrochemical stiffness of graphite-lithium intercalation compounds during cycling. They combined in situ electrochemical and mechanical measurement techniques to measure the intercalation-induced stress and strain of a graphite anode. The researchers used galvanostatic cycling and cyclic voltammetry, respectively, to assess the effects of capacity and electrochemical potential fluctuations on lithiation. The results are reported in a recent issue of Nature Materials (doi:10.1038/nmat4708).

Gewirth, in the Department of Chemistry, says, “For the first time we were able to correlate stress with strain during the lithiation event. Our finding that the two are asynchronous has important consequences for understanding and controlling battery behavior during charge and discharge.” Sottos, of the Department of Materials Science and Engineering, adds, “We are beginning to understand some of the factors that hinder faster battery charging. These experiments provide insight that it’s not just an electrochemical issue; the coupling to mechanics is also important.”

This unique in situ electrochemical stiffness measurement has already provided important information about the complex mechanical dynamical responses of electrodes during charging and discharging. In particular, a lithium-ion concentration gradient appears to be one of the biggest sources of stress on anodes. Kinetically limited lithium diffusion is less significant during slow charging but becomes a major stress factor during rapid cycling, and scales with the rate of charging. Ion insertion into the structure and the repulsion of nearby layers also act as additional sources of stress. In contrast, mechanical strain and material expansion strongly depend on ion intercalation and directly increase with slower charge rates. Unlike stress, electrochemically driven strain depends predominantly on the total capacity (i.e., stored charge) of the electrodes.

This research provides insight into the electromechanical coupling behavior of electrodes under their expected operating conditions. While certain energy-storage systems demand high charge and discharge rates, other uses prefer higher specific energy densities. Such a comprehensive in situ technique is vital for efforts to evaluate novel battery electrode materials and select compositions that are well tailored for specific applications.