Elasticity of Solids with a Large Concentration of Point Defects

Greenberg, Mark; Wachtel, Ellen; Lubomirsky, Igor; Fleig, Jürgen; Maier, Joachim

doi:10.1002/adfm.200500289

Cited by 65 publications

(68 citation statements)

References 24 publications

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“…[2] Let us consider a solid with large concentrations of two types of point defects, A and B, capable of interacting with each other via an association/dissociation reaction:…”

Section: Chemical Strain: Theorymentioning

confidence: 99%

“…The ionic conductivity in these materials originates in the large concentration (> 10 21 cm -3 ) of mobile point defects. [1] We have recently suggested (Part I, [2] ) that if, in addition to being highly mobile, the point defects can interact with each other, for instance form complexes or clusters, with associated volume change, then such materials may exhibit stress relaxation [3] via reversible defect association or dissociation. We have called this the chemical strain effect.…”

Section: Introduction: Stress-adaptable Materialsmentioning

confidence: 99%

“…The magnitude of this volume change is estimated to be b > 15 Å 3 . [2] Therefore, Ce 0.8 Gd 0.2 O 1.9 ceramics satisfy both requirements for potentially exhibiting the chemical strain effect: [2] they contain a large concentration of highly mobile point defects and the point defects interact causing significant volume change. Here we report that, indeed, self-supported nanocrystalline films of Ce 0.8 Gd 0.2 O 1.9 experience a fully reversible change of linear dimensions in response to variation of external mechanical constraints.…”

Section: Introduction: Stress-adaptable Materialsmentioning

confidence: 99%

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Elasticity of Solids with a Large Concentration of Point Defects II. The Chemical Strain Effect in Ce_0.8Gd_0.2O_1.9

Kossoy¹,

Feldman²,

Wachtel³

et al. 2007

Adv Funct Materials

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The chemical strain effect describes a mechanism of stress relaxation in solids that can be attributed to the conversion of elastic energy into chemical energy of point defects. Experimental confirmation of this effect is presented here for the case of thin self‐supported films of the ionic conductor Ce0.8Gd0.2O1.9. If heated slowly, (< 5 °C min–1) these films remain flat within the temperature range of 25–180 °C. If heated more rapidly than ∼ 20 °C min–1, the films buckle above 53 °C, but after ∼ 3–30 min at elevated temperatures, they become flat again, demonstrating that stress‐relaxation has taken place. The degree of stress reduction observed is consistent with the value calculated for this system using Boltzmann statistics in the case of small strain. These findings confirm the concept of stress adaptability in solids that we introduced in Part I and suggest that a large class of such materials, which exhibit the chemical strain effect, is likely to be found.

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“…[2] Let us consider a solid with large concentrations of two types of point defects, A and B, capable of interacting with each other via an association/dissociation reaction:…”

Section: Chemical Strain: Theorymentioning

confidence: 99%

Section: Introduction: Stress-adaptable Materialsmentioning

confidence: 99%

Section: Introduction: Stress-adaptable Materialsmentioning

confidence: 99%

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Elasticity of Solids with a Large Concentration of Point Defects II. The Chemical Strain Effect in Ce_0.8Gd_0.2O_1.9

Kossoy¹,

Feldman²,

Wachtel³

et al. 2007

Adv Funct Materials

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“…In addition to being detrimental to mechanical reliability, mechanical stresses can also alter the ionic transport in the electrolyte, thus affecting the electrochemical performance of the SOFC [19]. For example, it was shown [20] that defect association and dissociation may take place in 20 GDC through stress relaxation mechanisms owing to the coupling between mechanical stresses and electrochemical reactions. An uphill transport of oxygen ions in solid electrolytes was demonstrated [21] by measuring the polarization voltage across the faces of doped zirconia beam subject to bending.…”

Section: Introductionmentioning

confidence: 97%

Interactions Between Non‐Stoichiometric Stresses and Defect Transport in a Tubular Electrolyte

Swaminathan¹,

Qu²

2007

Fuel Cells

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It is well known that gadolinium doped ceria (10 GDC) undergoes significant compositional expansion when exposed to low oxygen partial pressures. When constrained, such expansion results in mechanical stresses in the ionic solid. Although significant work has been done in evaluating the magnitudes of this expansion, interactions between stresses induced as a result of chemical expansion and transport of point defects in a solid electrolyte have not received much attention. In this work, the formulation developed by Swaminathan et al. in ref. [1] for coupling transport and mechanical stresses in an ionic solid is used to numerically study the effects of transport–stress interaction in a tubular solid electrolyte made of 10 GDC. The results obtained in this study indicate a strong interaction between transport and stresses, showing a significant variation in the electrochemical performance of the electrolyte under varying conditions of stress–transport interaction. The solutions obtained in this study reduce to the well‐known results in the literature when chemical expansion is not considered, thereby partially validating our results.

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“…Microstructural features, such as the small grain size, texture, varying degrees of crystallinity, residual amorphous phases, and microstrains, form the nanoimpact on thermal and electric properties of electrolyte thin films. It was seen that nanocrystalline materials show unusual electrical conductivities [39][40][41][42] and thermal stabilities [43][44][45], because of the large amount of grain boundaries these materials contain in relation to the grain volume. In the case of nanocrystalline thin films, stresses within the films, which result from thermal expansion mismatch between the substrate and the thin films, can affect the electrical properties and must be taken into consideration for their application in SOFCs [46].…”

Section: Electrolytementioning

confidence: 99%

Micro-solid oxide fuel cells: status, challenges, and chances

et al. 2009

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Micro-solid oxide fuel cells (micro-SOFC) are predicted to be of high energy density and are potential power sources for portable electronic devices. A micro-SOFC system consists of a fuel cell comprising a positive electrode-electrolyte-negative electrode (i.e. PEN) element, a gas-processing unit, and a thermal system where processing is based on micro-electro-mechanical-systems fabrication techniques. A possible system approach is presented. The critical properties of the thin film materials used in the PEN membrane are discussed, and the unsolved subtasks related to micro-SOFC membrane development are pointed out. Such a micro-SOFC system approach seems feasible and offers a promising alternative to stateof-the-art batteries in portable electronics.

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Elasticity of Solids with a Large Concentration of Point Defects

Cited by 65 publications

References 24 publications

Elasticity of Solids with a Large Concentration of Point Defects II. The Chemical Strain Effect in Ce_0.8Gd_0.2O_1.9

Elasticity of Solids with a Large Concentration of Point Defects II. The Chemical Strain Effect in Ce_0.8Gd_0.2O_1.9

Interactions Between Non‐Stoichiometric Stresses and Defect Transport in a Tubular Electrolyte

Micro-solid oxide fuel cells: status, challenges, and chances

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Elasticity of Solids with a Large Concentration of Point Defects

Cited by 65 publications

References 24 publications

Elasticity of Solids with a Large Concentration of Point Defects II. The Chemical Strain Effect in Ce0.8Gd0.2O1.9

Elasticity of Solids with a Large Concentration of Point Defects II. The Chemical Strain Effect in Ce0.8Gd0.2O1.9

Interactions Between Non‐Stoichiometric Stresses and Defect Transport in a Tubular Electrolyte

Micro-solid oxide fuel cells: status, challenges, and chances

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Resources

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Elasticity of Solids with a Large Concentration of Point Defects II. The Chemical Strain Effect in Ce_0.8Gd_0.2O_1.9

Elasticity of Solids with a Large Concentration of Point Defects II. The Chemical Strain Effect in Ce_0.8Gd_0.2O_1.9