Emerging Electron Microscopy Techniques for Probing Functional Interfaces in Energy Materials

Zachman, Michael J.; Hachtel, Jordan A.; Idrobo, Juan Carlos; Chi, Miaofang

doi:10.1002/ange.201902993

Cited by 9 publications

(10 citation statements)

References 159 publications

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“…A few studies report on the crystallographic orientation of Zn deposits obtained with pulsed protocol (192,193). The correlation is, however, not straightforward, unlike what has been shown for Cu deposition-Strong (111), (100), and (101) textures can be achieved respectively by optimization of the pulse parameter (194). In light of the greater crystal anisotropy of Zn than Cu, we speculate that similar quality of texturing can be realized in Zn systems, which warrants further explorations.…”

Section: Approaches For Regulating Morphology Of Metal Electrodepositsmentioning

confidence: 72%

“…Similarly, the Zn structure shown in Fig. 4C also extends along a low-index zone axis, i.e., [1 ¯ 2 0], allowing the exposure of (002) and (100). The analogy between Li and Zn further suggests that the moss-like Zn electrodeposits are formed in a SEI-dominated regime.…”

Section: Chemistry Of the Electrolyte And The Seimentioning

confidence: 89%

“…For example, some claim that Zn 4 SO 4 (OH) 6 •4H 2 O is also detected on electrodeposited Zn metal (97)(98)(99), as opposed to the ZnO observed in other studies as mentioned. Advanced characterization techniques, e.g., high-resolution TEM/scanning TEM, could provide important insights into the SEI of Zn metal to resolve these remaining questions about the nature of SEI and the role it plays in electrodeposition, particularly considering that Zn metal samples are not as sensitive to atmosphere or to beam damage as Li samples are (100).…”

Section: Chemistry Of the Electrolyte And The Seimentioning

confidence: 99%

See 2 more Smart Citations

Controlling electrochemical growth of metallic zinc electrodes: Toward affordable rechargeable energy storage systems

2021

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Scalable approaches for precisely manipulating the growth of crystals are of broad-based science and technological interest. New research interests have reemerged in a subgroup of these phenomena—electrochemical growth of metals in battery anodes. In this Review, the geometry of the building blocks and their mode of assembly are defined as key descriptors to categorize deposition morphologies. To control Zn electrodeposit morphology, we consider fundamental electrokinetic principles and the associated critical issues. It is found that the solid-electrolyte interphase (SEI) formed on Zn has a similarly strong influence as for alkali metals at low current regimes, characterized by a moss-like morphology. Another key conclusion is that the unique crystal structure of Zn, featuring high anisotropy facets resulting from the hexagonal close-packed lattice with a c/a ratio of 1.85, imposes predominant influences on its growth. In our view, precisely regulating the SEI and the crystallographic features of the Zn offers exciting opportunities that will drive transformative progress.

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Section: Approaches For Regulating Morphology Of Metal Electrodepositsmentioning

confidence: 72%

Section: Chemistry Of the Electrolyte And The Seimentioning

confidence: 89%

Section: Chemistry Of the Electrolyte And The Seimentioning

confidence: 99%

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Controlling electrochemical growth of metallic zinc electrodes: Toward affordable rechargeable energy storage systems

2021

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“…Emerging electron microscopy techniques, based on scanning transmission electron microscopy (STEM) and/or electron energy loss spectroscopy (EELS) (such as 4D-STEM, cryo-STEM, and monochromated EELS) are very useful tools for probing functional interfaces in energy materials (as shown typically in Fig. 1 ) 24 , 25 . Spatially resolved EELS is capable of examining the conduction band structure and has been used to study the electronic changes at perovskite oxide heterointerfaces 7 , 26 , 27 .…”

Section: Introductionmentioning

confidence: 99%

Determination of the embedded electronic states at nanoscale interface via surface-sensitive photoemission spectroscopy

Wang

Lin

et al. 2021

Light Sci Appl

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The fabrication of small-scale electronics usually involves the integration of different functional materials. The electronic states at the nanoscale interface plays an important role in the device performance and the exotic interface physics. Photoemission spectroscopy is a powerful technique to probe electronic structures of valence band. However, this is a surface-sensitive technique that is usually considered not suitable for the probing of buried interface states, due to the limitation of electron-mean-free path. This article reviews several approaches that have been used to extend the surface-sensitive techniques to investigate the buried interface states, which include hard X-ray photoemission spectroscopy, resonant soft X-ray angle-resolved photoemission spectroscopy and thickness-dependent photoemission spectroscopy. Especially, a quantitative modeling method is introduced to extract the buried interface states based on the film thickness-dependent photoemission spectra obtained from an integrated experimental system equipped with in-situ growth and photoemission techniques. This quantitative modeling method shall be helpful to further understand the interfacial electronic states between functional materials and determine the interface layers.

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“…As atomic-resolution imaging and spectroscopy of crystalline materials at room temperature has become almost routine, the interest in cryogenic electron microscopy for the physical sciences has been renewed (El Baggari & Kourkoutis, 2019; Minor et al, 2019; Zachman et al, 2020). Recent results have demonstrated the potential for cryogenic scanning transmission electron microscopy (STEM) and electron energy loss spectroscopy to explore quantum materials phenomena including low-temperature spin states (Klie et al, 2007), emergent charge density phases (El Baggari et al, 2018), and interface charge transfer (Zhao et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Atomic-Resolution Cryo-STEM Across Continuously Variable Temperatures

et al. 2020

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Atomic-resolution cryogenic scanning transmission electron microscopy (cryo-STEM) has provided a path to probing the microscopic nature of select low-temperature phases in quantum materials. Expanding cryo-STEM techniques to broadly tunable temperatures will give access to the rich temperature-dependent phase diagrams of these materials. With existing cryo-holders, however, variations in sample temperature significantly disrupt the thermal equilibrium of the system, resulting in large-scale sample drift. The ability to tune the temperature without negative impact on the overall instrument stability is crucial, particularly for high-resolution experiments. Here, we test a new side-entry continuously variable temperature dual-tilt cryo-holder which integrates liquid nitrogen cooling with a 6-pin micro-electromechanical system (MEMS) sample heater to overcome some of these experimental challenges. We measure consistently low drift rates of 0.3–0.4 Å/s and demonstrate atomic-resolution cryo-STEM imaging across a continuously variable temperature range from ~100 K to well above room temperature. We conduct additional drift stability measurements across several commercial sample stages and discuss implications for further developments of ultra-stable, flexible cryo-stages.

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Emerging Electron Microscopy Techniques for Probing Functional Interfaces in Energy Materials

Cited by 9 publications

References 159 publications

Controlling electrochemical growth of metallic zinc electrodes: Toward affordable rechargeable energy storage systems

Controlling electrochemical growth of metallic zinc electrodes: Toward affordable rechargeable energy storage systems

Determination of the embedded electronic states at nanoscale interface via surface-sensitive photoemission spectroscopy

Atomic-Resolution Cryo-STEM Across Continuously Variable Temperatures

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