Local Multimodal Electro‐Chemical‐Structural Characterization of Solid‐Electrolyte Grain Boundaries

Xu, Xin; Carr, Christopher; Chen, Xinqi; Myers, Benjamin D.; Huang, Ruiyun; Yuan, Weizi; Choi, Sihyuk; Yi, Dezhi; Phatak, Charudatta; Haile, Sossina M.

doi:10.1002/aenm.202003309

Cited by 10 publications

(13 citation statements)

References 55 publications

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“…One particularly promising but so far unexplored possibility is to investigate the impedance characteristics of individual isolated domain walls in nanostructured samples, analogous to so-called bicrystals (see Figure 4c). [153] By performing measurements on samples containing individual ferroelectric domain walls, an unprecedented frequency range could be covered within a single experiment, enabling a systematic analysis of features in the dielectric spectra and their relation to, e.g., the domain wall orientation and charge state.…”

Section: Conclusion and Future Perspectivementioning

confidence: 99%

“…b) The application of AFM-based techniques, such as NIM, [102,103] SIM, [104] and AC-cAFM, [23] enables spectroscopy measurements at ferroelectric domain walls with nanoscale spatial resolution. c) Analogous to bicrystals, [153] which were used in studies on grain-boundary-related effects in polycrystalline ceramics, the investigation of nanostructured ferroelectrics with only one domain wall represents a powerful approach for future frequency-dependent investigations.…”

Section: Figurementioning

confidence: 99%

“…This facilitated impedance characterization of the grain boundary from 1 mHz to 1 MHz at temperatures from 300 to 500 °C. [153] Although FIB-based extraction of domain walls in ferroelectric materials has been demonstrated, [119,209] the impedance characteristics of the microscopic crystals, as proposed in Figure 4c, have so far not been analyzed.…”

Section: Microscale Bicrystalsmentioning

confidence: 99%

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Unveiling Alternating Current Electronic Properties at Ferroelectric Domain Walls

Schultheiß

Rojac

Meier

2021

Adv Elect Materials

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Ferroelectric domain walls exhibit a range of interesting electrical properties and are now widely recognized as functional 2D systems for the development of next‐generation nanoelectronics. A major achievement in the field is the development of a fundamental framework that explains the emergence of enhanced electronic direct‐current conduction at the domain walls. Here, the much less explored behavior of ferroelectric domain walls under applied alternating‐current (AC) voltages is discussed. An overview of the recent advances in the nanoscale characterization is provided that allows for resolving the dynamic responses of individual domain walls to AC fields. In addition, different examples are presented, showing the unusual AC electronic properties that arise at neutral and charged domain walls in the kilo‐ to gigahertz regime. It is concluded with a discussion about the future direction of the field and novel application opportunities, expanding domain‐wall‐based nanoelectronics into the realm of AC technologies.

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Section: Conclusion and Future Perspectivementioning

confidence: 99%

Section: Figurementioning

confidence: 99%

Section: Microscale Bicrystalsmentioning

confidence: 99%

See 1 more Smart Citation

Unveiling Alternating Current Electronic Properties at Ferroelectric Domain Walls

Schultheiß

Rojac

Meier

2021

Adv Elect Materials

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“…Similarly, assessments of variability of transport parameters, including local conductivity, electrical width, core charge, and activation energy, can complement such structural and chemical studies. A combination of ac and dc electrical measurements, SIMS, and EBSD imaging has recently been applied to observe variability in grain boundaries of CeO 2 bicrystal fibers and has provided insight into the chemical origin of the variability in core charge . Similarly, Xu et al .…”

Section: Opportunities Questions and Challengesmentioning

confidence: 99%

“…A combination of ac and dc electrical measurements, SIMS, and EBSD imaging has recently been applied to observe variability in grain boundaries of CeO 2 bicrystal fibers and has provided insight into the chemical origin of the variability in core charge. 61 Similarly, Xu et al combined atom probe tomography with electron holography to provide insight into the diversity of space charge potentials among grain boundaries in polycrystalline (Ce,Sm)O 2 . 62 Analysis of transport anisotropy can be performed by creating ordered arrays of aligned dislocations and performing macroscopic transport measurements parallel and perpendicular to the alignment direction.…”

Section: Effects Of Dislocations On Transportmentioning

confidence: 99%

Dislocation-Mediated Conductivity in Oxides: Progress, Challenges, and Opportunities

et al. 2021

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Dislocations in ionic solids are topological extended defects that modulate composition, strain, and charge over multiple length scales. As such, they provide an extra degree of freedom to tailor ionic and electronic transport beyond limits inherent in bulk doping. Heterogeneity of transport paths as well as the ability to dynamically reconfigure structure and properties through multiple stimuli lend dislocations to particular potential applications including memory, switching, non-Ohmic electronics, capacitive charge storage, and single-atom catalysis. However, isolating, understanding, and predicting causes of modified transport behavior remain a challenge. In this Perspective, we first review existing reports of dislocation-modified transport behavior in oxides, as well as synthetic strategies and multiscale characterization routes to uncover processing−structure−property relationships. We outline a vision for future research, suggesting outstanding questions, tasks, and opportunities. Advances in this field will require highly interdisciplinary, convergent computational−experimental approaches, covering orders of magnitude in length scale, and spanning fields from microscopy and machine learning to electro-chemo-mechanics and point defect chemistry to transport-by-design and advanced manufacturing.

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Understanding the evolution of lithium dendrites at Li6.25Al0.25La3Zr2O12 grain boundaries via operando microscopy techniques

et al. 2023

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The growth of lithium dendrites in inorganic solid electrolytes is an essential drawback that hinders the development of reliable all-solid-state lithium metal batteries. Generally, ex situ post mortem measurements of battery components show the presence of lithium dendrites at the grain boundaries of the solid electrolyte. However, the role of grain boundaries in the nucleation and dendritic growth of metallic lithium is not yet fully understood. Here, to shed light on these crucial aspects, we report the use of operando Kelvin probe force microscopy measurements to map locally time-dependent electric potential changes in the Li6.25Al0.25La3Zr2O12 garnet-type solid electrolyte. We find that the Galvani potential drops at grain boundaries near the lithium metal electrode during plating as a response to the preferential accumulation of electrons. Time-resolved electrostatic force microscopy measurements and quantitative analyses of lithium metal formed at the grain boundaries under electron beam irradiation support this finding. Based on these results, we propose a mechanistic model to explain the preferential growth of lithium dendrites at grain boundaries and their penetration in inorganic solid electrolytes.

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Local Multimodal Electro‐Chemical‐Structural Characterization of Solid‐Electrolyte Grain Boundaries

Cited by 10 publications

References 55 publications

Unveiling Alternating Current Electronic Properties at Ferroelectric Domain Walls

Unveiling Alternating Current Electronic Properties at Ferroelectric Domain Walls

Dislocation-Mediated Conductivity in Oxides: Progress, Challenges, and Opportunities

Understanding the evolution of lithium dendrites at Li6.25Al0.25La3Zr2O12 grain boundaries via operando microscopy techniques

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