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Main Authors: Wagner, Tolga, Niermann, Tore, Urban, Felix, Lehmann, Michael
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2405.08845
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author Wagner, Tolga
Niermann, Tore
Urban, Felix
Lehmann, Michael
author_facet Wagner, Tolga
Niermann, Tore
Urban, Felix
Lehmann, Michael
contents The interference gating is a novel method for robust time-resolved electron holographic measurements by directly switching the interference. Here, a new arrangement is presented in which a biprism in the condenser aperture as a fast electric phase shifter is used to control the interference pattern. High-frequency stimulation of the electric phase shifter in the gigahertz range are performed and observed via electron holography, proving the feasibility of interference gating in the upper picosecond range. Despite the bandwidth limitation of 180~MHz of the current signal generator, a time resolution of 100 nanoseconds is achieved through forward correction of the control signal. With this time resolution, it is already possible to measure the transient response of the biasing holder system. Our method paves the way towards a closer look on fast dynamic processes with high temporal and spatial resolution.
format Preprint
id arxiv_https___arxiv_org_abs_2405_08845
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Nanosecond Electron Holography by Interference Gating
Wagner, Tolga
Niermann, Tore
Urban, Felix
Lehmann, Michael
Applied Physics
Optics
The interference gating is a novel method for robust time-resolved electron holographic measurements by directly switching the interference. Here, a new arrangement is presented in which a biprism in the condenser aperture as a fast electric phase shifter is used to control the interference pattern. High-frequency stimulation of the electric phase shifter in the gigahertz range are performed and observed via electron holography, proving the feasibility of interference gating in the upper picosecond range. Despite the bandwidth limitation of 180~MHz of the current signal generator, a time resolution of 100 nanoseconds is achieved through forward correction of the control signal. With this time resolution, it is already possible to measure the transient response of the biasing holder system. Our method paves the way towards a closer look on fast dynamic processes with high temporal and spatial resolution.
title Nanosecond Electron Holography by Interference Gating
topic Applied Physics
Optics
url https://arxiv.org/abs/2405.08845