Design and simulation of a linear electron cavity for quantum electron microscopy

Marco Turchetti; Chung Soo Kim; Richard Hobbs; Yujia Yang; Pieter Kruit; Karl K. Berggren

doi:10.1016/j.ultramic.2019.01.010

Design and simulation of a linear electron cavity for quantum electron microscopy

Marco Turchetti^*, Chung Soo Kim, Richard Hobbs, Yujia Yang, Pieter Kruit, Karl K. Berggren

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

8 Citations (Scopus)

Abstract

Quantum electron microscopy (QEM) is a measurement approach that could reduce sample radiation damage, which represents the main obstacle to sub-nanometer direct imaging of molecules in conventional electron microscopes. This method is based on the exploitation of interaction-free measurements in an electron resonator. In this work, we present the design of a linear resonant electron cavity, which is at the core of QEM. We assess its stability and optical properties during resonance using ray-tracing electron optical simulations. Moreover, we analyze the issue of spherical aberrations inside the cavity and we propose and verify through simulation two possible approaches to the problem. Finally, we discuss some of the important design parameters and constraints, such as conservation of temporal coherence and effect of alignment fields.

Original language	English
Pages (from-to)	50-61
Journal	Ultramicroscopy
Volume	199
DOIs	https://doi.org/10.1016/j.ultramic.2019.01.010
Publication status	Published - 2019

Keywords

Interaction-free measurement
Quantum electron microscopy
Radiation damage
Spherical aberration

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10.1016/j.ultramic.2019.01.010

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title = "Design and simulation of a linear electron cavity for quantum electron microscopy",

abstract = "Quantum electron microscopy (QEM) is a measurement approach that could reduce sample radiation damage, which represents the main obstacle to sub-nanometer direct imaging of molecules in conventional electron microscopes. This method is based on the exploitation of interaction-free measurements in an electron resonator. In this work, we present the design of a linear resonant electron cavity, which is at the core of QEM. We assess its stability and optical properties during resonance using ray-tracing electron optical simulations. Moreover, we analyze the issue of spherical aberrations inside the cavity and we propose and verify through simulation two possible approaches to the problem. Finally, we discuss some of the important design parameters and constraints, such as conservation of temporal coherence and effect of alignment fields.",

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T1 - Design and simulation of a linear electron cavity for quantum electron microscopy

AU - Turchetti, Marco

AU - Kim, Chung Soo

AU - Hobbs, Richard

AU - Yang, Yujia

AU - Kruit, Pieter

AU - Berggren, Karl K.

PY - 2019

Y1 - 2019

N2 - Quantum electron microscopy (QEM) is a measurement approach that could reduce sample radiation damage, which represents the main obstacle to sub-nanometer direct imaging of molecules in conventional electron microscopes. This method is based on the exploitation of interaction-free measurements in an electron resonator. In this work, we present the design of a linear resonant electron cavity, which is at the core of QEM. We assess its stability and optical properties during resonance using ray-tracing electron optical simulations. Moreover, we analyze the issue of spherical aberrations inside the cavity and we propose and verify through simulation two possible approaches to the problem. Finally, we discuss some of the important design parameters and constraints, such as conservation of temporal coherence and effect of alignment fields.

AB - Quantum electron microscopy (QEM) is a measurement approach that could reduce sample radiation damage, which represents the main obstacle to sub-nanometer direct imaging of molecules in conventional electron microscopes. This method is based on the exploitation of interaction-free measurements in an electron resonator. In this work, we present the design of a linear resonant electron cavity, which is at the core of QEM. We assess its stability and optical properties during resonance using ray-tracing electron optical simulations. Moreover, we analyze the issue of spherical aberrations inside the cavity and we propose and verify through simulation two possible approaches to the problem. Finally, we discuss some of the important design parameters and constraints, such as conservation of temporal coherence and effect of alignment fields.

KW - Interaction-free measurement

KW - Quantum electron microscopy

KW - Radiation damage

KW - Spherical aberration

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DO - 10.1016/j.ultramic.2019.01.010

M3 - Article

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SN - 0304-3991

VL - 199

SP - 50

EP - 61

JO - Ultramicroscopy

JF - Ultramicroscopy

ER -

Design and simulation of a linear electron cavity for quantum electron microscopy

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Keywords

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