Detecting dynamic responses of materials and devices under an alternating electric potential by phase-locked transmission electron microscopy. Soma, K., Konings, S., Aso, R., Kamiuchi, N., Kobayashi, G., Yoshida, H., & Takeda, S. Ultramicroscopy, 181:27–41, October, 2017.
Detecting dynamic responses of materials and devices under an alternating electric potential by phase-locked transmission electron microscopy [link]Paper  doi  abstract   bibtex   
An apparatus is developed for transmission electron microscopy (TEM) to acquire image and spectral data, such as TEM images, electron holograms, and electron energy loss spectra, synchronized with the measurement of the dynamic response of a specimen under an applied alternating current (AC) electric potential (voltage, denoted VAC). From a VAC of frequency f, a shutter pulse signal is generated to open and close a pre-specimen shutter in a base TEM apparatus. A pulse is generated per VAC cycle from the targeted phase Φ to Φ +∆Φ with phase width ∆Φ (∆Φ \textless2π). ∆Φ corresponds to the temporal pulse width τ (τ \textless 1/f) of an electron beam; i.e., ∆Φ =2πfτ. Because of the high sensitivity of the TEM camera used in this study, the images and spectra that are acquired at the same target phase are integrated by means of stroboscopic illumination to obtain the final phase-locked images and spectra with sufficiently small S/N ratio. Phase-locked (strobe) images and/or spectra are obtained for model specimens of polycrystalline aluminum and an all-solid-state lithium ion battery (LIB). In the phase-locked TEM conditions, f ranges from 1Hz to about 40kHz and ∆Φ from 2π/80 to π. VAC ranges from 2mV to 1V depending on observation conditions. The quality of phase-locked strobe images can be improved markedly using a phase-locked strobe electron beam. Under specific conditions, the spatial resolution in images is better than 0.12nm, even though the spatial resolution generally depends on VAC, f, the base TEM, and the conductivity of the specimen. For the model specimens, it is shown that electrochemical impedance spectroscopy and cyclic voltammetry can be performed in a TEM apparatus, and could potentially be synchronized with phase-locked (strobe) imaging and spectroscopy. Severe electron irradiation damage is detected during phase-locked (strobe) electron holography of the model LIB.
@article{soma_detecting_2017,
	title = {Detecting dynamic responses of materials and devices under an alternating electric potential by phase-locked transmission electron microscopy},
	volume = {181},
	issn = {0304-3991},
	url = {http://www.sciencedirect.com/science/article/pii/S0304399116303965},
	doi = {10.1016/j.ultramic.2017.04.018},
	abstract = {An apparatus is developed for transmission electron microscopy (TEM) to acquire image and spectral data, such as TEM images, electron holograms, and electron energy loss spectra, synchronized with the measurement of the dynamic response of a specimen under an applied alternating current (AC) electric potential (voltage, denoted VAC). From a VAC of frequency f, a shutter pulse signal is generated to open and close a pre-specimen shutter in a base TEM apparatus. A pulse is generated per VAC cycle from the targeted phase Φ to Φ +∆Φ with phase width ∆Φ (∆Φ {\textless}2π). ∆Φ corresponds to the temporal pulse width τ (τ {\textless} 1/f) of an electron beam; i.e., ∆Φ =2πfτ. Because of the high sensitivity of the TEM camera used in this study, the images and spectra that are acquired at the same target phase are integrated by means of stroboscopic illumination to obtain the final phase-locked images and spectra with sufficiently small S/N ratio. Phase-locked (strobe) images and/or spectra are obtained for model specimens of polycrystalline aluminum and an all-solid-state lithium ion battery (LIB). In the phase-locked TEM conditions, f ranges from 1Hz to about 40kHz and ∆Φ from 2π/80 to π. VAC ranges from 2mV to 1V depending on observation conditions. The quality of phase-locked strobe images can be improved markedly using a phase-locked strobe electron beam. Under specific conditions, the spatial resolution in images is better than 0.12nm, even though the spatial resolution generally depends on VAC, f, the base TEM, and the conductivity of the specimen. For the model specimens, it is shown that electrochemical impedance spectroscopy and cyclic voltammetry can be performed in a TEM apparatus, and could potentially be synchronized with phase-locked (strobe) imaging and spectroscopy. Severe electron irradiation damage is detected during phase-locked (strobe) electron holography of the model LIB.},
	urldate = {2017-07-28},
	journal = {Ultramicroscopy},
	author = {Soma, Kentaro and Konings, Stan and Aso, Ryotaro and Kamiuchi, Naoto and Kobayashi, Genki and Yoshida, Hideto and Takeda, Seiji},
	month = oct,
	year = {2017},
	keywords = {All-solid-state lithium ion battery, Electron energy loss spectroscopy, Electron holography, Phase-locked strobe transmission electron microscopy, electrochemical impedance spectroscopy},
	pages = {27--41},
}
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