Chemomechanics of ionically conductive ceramics for electrical energy conversion and storage

Swallow, Jessica G.; Woodford, William H.; Chen, Y.; Lu, Qiyang; Kim, J. J.; Chen, D.; Chiang, Yet‐Ming; Carter, W. C.; Yildiz, Bilge; Tuller, Harry L.; Vliet, Krystyn J. Van

doi:10.1007/s10832-013-9872-2

Cited by 37 publications

(33 citation statements)

References 196 publications

(222 reference statements)

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“…On this basis, we note that actuation is most likely achieved via an electrochemically driven phase transformation, rather than because of the change in stoichiometry of a single phase . This can be distinguished from the chemical expansion of ion‐conducting ceramics, or of polymers …”

Section: Resultsmentioning

confidence: 99%

“…Therefore, electrochemical oxygen exchange reactions at the interface with a titanium electrode is possible even at room temperature. These electrochemical reactions may induce electro‐chemomechanical (ECM) response, i.e., mechanical deformation induced by electrochemically driven changes in composition . Therefore, ECM and electrostrictive responses may superimpose.…”

Section: Introductionmentioning

confidence: 99%

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Electro‐chemomechanical Contribution to Mechanical Actuation in Gd‐Doped Ceria Membranes

Mishuk

Ушаков

Makagon

et al. 2019

Adv Materials Inter

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Gd‐doped ceria (CGO), one of the most extensively studied oxygen ion conductors, is a low dielectric constant/low mechanical compliance material exhibiting large nonclassical electrostriction. The electromechanical response of the micro‐electromechanical devices with CGO films as an active material described previously can not be attributed exclusively to electrostriction. Here it is shown that, below 1 Hz, in addition to electrostriction (second‐harmonic response), there is a strong contribution of the electro‐chemomechanical effect (ECM, first harmonic response). ECM is the change in mechanical dimensions of ionic and mixed ionic‐electronic conductors as a result of a change in chemical composition induced by an electric field. In batteries, the presence of ECM is highly detrimental. In ceria at room temperature, it was considered to be negligible because of slow oxygen diffusion. This work demonstrates ECM actuation at ambient temperature and moderate electric field (<5 V µm−1). ECM‐induced strain is attributed to reversible oxidation/ reduction of TiO2 layers at the Ti‐CGO interface. At 25 °C, the ECM bending strain is 1.2 × 10−6, increasing exponentially with temperature. These data suggest that with a proper choice of materials, ECM‐type response can be a viable mechanism for mechanical actuation at ambient and also at slightly elevated temperatures.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Electro‐chemomechanical Contribution to Mechanical Actuation in Gd‐Doped Ceria Membranes

Mishuk

Ушаков

Makagon

et al. 2019

Adv Materials Inter

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“…24,26,27,33 Acoustic emission from electrochemical shock has also been directly recorded during charging and discharging. [28][29][30][31][32][34][35][36] Here, TXM was used to non-destructively generate 3D tomographs of the single particles at different states of charge, which we correlate with the electrochemical measurements. Individual NMC333 and NCA single particles having B10 mm diameter were charged at C/3 rate to 3.9 V, 4.1 V, and 4.5 V, respectively.…”

Section: Txm Observations Of 3d Microstructural Evolutionmentioning

confidence: 99%

Single-particle measurements of electrochemical kinetics in NMC and NCA cathodes for Li-ion batteries

Tsai

Wen

Wolfman

et al. 2018

Energy Environ. Sci.

242

228

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aThe electrochemical kinetics of battery electrodes at the single-particle scale are measured as a function of state-of-charge, and interpreted with the aid of concurrent transmission X-ray microscopy (TXM) of the evolving particle microstructure. An electrochemical cell operating with near-picoampere current resolution is used to characterize single secondary particles of two widely-used cathode compounds, NMC333 and NCA. Interfacial charge transfer kinetics are found to vary by two orders of magnitude with state-of-charge (SOC) in both materials, but the origin of the SOC dependence differs greatly. NCA behavior is dominated by electrochemically-induced microfracture, although thin binder coatings significantly ameliorate mechanical degradation, while NMC333 demonstrates strongly increasing interfacial reaction rates with SOC for chemical reasons. Micro-PITT is used to separate interfacial and bulk transport rates, and show that for commercially relevant particle sizes, interfacial transport is rate-limiting at low SOC, while mixed-control dominates at higher SOC. These results provide mechanistic insight into the mesoscale kinetics of ion intercalation compounds, which can guide the development of high performance rechargeable batteries. Broader contextThe performance of high performance Li-ion batteries, central to both electric transportation and grid scale storage, is ultimately reliant on the performance of critical components such as their cathode and anode compounds. For ease of manufacturing, the prevailing technological forms of these materials are secondary particles of nearly spherical morphology containing many nanocrystallites. The electrochemical kinetics at this critical length scale have been difficult to assess; particle-level behavior has primarily been deduced from macroscale cell measurements. Thus the microelectrode technique developed in this work, combined with state-of-the-art TXM imaging, allows for the first time the direct measurement of electrochemical kinetics of particles as they are charged and discharged. Surprising behavior is revealed -interfacial charge transfer kinetics are found to vary greatly with state-of-charge and cycling history, both for intrinsic chemical reasons (in NMC333) and because of massively damaging ''electrochemical shock'' (in NCA). Moreover, a thin coating of polymer binder is found to ameliorate fracture damage. These results, and the techniques demonstrated, provide a bridge between macroscopic battery function and microscale electrode kinetics as influenced by electrochemomechanical stress and charging history.

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“…On the other hand, theoretical calculation and simulations suggest that interfacial tensile strain is beneficial and can improve the oxygen ionic conductivity through changes in the hopping sites and frequencies, due to a substantial variation of the enthalpies of oxygen-vacancy migration and association [104]. The key factors for enabling fast oxygen transport in strained lattice have been thus discussed in a growing number of publications describing the combined electro-chemo-mechanic effects on oxygen ion conductivity both on biaxial and isotropic strain [104,105]. Particularly, Sousa et al have employed static lattice simulations to examine the effect of isotropic and biaxial strain on the migration thermodynamics of oxygen vacancies in fluorite-structured ceria.…”

Section: Effect Of Strainmentioning

confidence: 99%

When two become one: An insight into 2D conductive oxide interfaces

Pryds

Esposito

2016

J Electroceram

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Chemomechanics of ionically conductive ceramics for electrical energy conversion and storage

Cited by 37 publications

References 196 publications

Electro‐chemomechanical Contribution to Mechanical Actuation in Gd‐Doped Ceria Membranes

Electro‐chemomechanical Contribution to Mechanical Actuation in Gd‐Doped Ceria Membranes

Single-particle measurements of electrochemical kinetics in NMC and NCA cathodes for Li-ion batteries

When two become one: An insight into 2D conductive oxide interfaces

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