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Ultrafast High-Energy Electron Radiography Application in Magnetic Field Delicate Structure Measurement

Published online by Cambridge University Press:  01 January 2024

J. H. Xiao
Affiliation:
Department of Engineering Physics, Tsinghua University, Beijing 100084, China Key Laboratory of Particle & Radiation Imaging (Tsinghua University), Ministry of Education, Beijing 100084, China
Y. C. Du*
Affiliation:
Department of Engineering Physics, Tsinghua University, Beijing 100084, China Key Laboratory of Particle & Radiation Imaging (Tsinghua University), Ministry of Education, Beijing 100084, China
S. Z. Zhang
Affiliation:
Xi’an Jiaotong University, Xi’an 710049, China
Y. T. Zhao
Affiliation:
Xi’an Jiaotong University, Xi’an 710049, China
*
Correspondence should be addressed to Y. C. Du; [email protected]
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Abstract

Transient electromagnetic field plays very important roles in the evolution of high-energy-density matter or laser plasma. Now, a new design is proposed in this paper to diagnose the transient magnetic field, using relativistic electron bunch as a probe based on high-energy electron radiography. And based on this scheme, the continuous distribution of magnetic strength field can be snapshotted. For 1 mm thick quadrupole magnet model measured by 50 MeV probe electron beams, the simulation result indicates that this diagnosis has spatial resolution better than 4 microns and high measurement accuracy for strong magnetic strength and high magnetic gradient field no matter whether the magnetic interaction is focusing or defocusing for the range from -510 T μm to 510 T μm.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © 2021 J. H. Xiao et al.

1. Introduction

The transient electromagnetic field plays very important roles in the research on the high-energy-density matter, driven by intense laser, ion, and Z-pinch equipment [Reference Haines1Reference Brynolf, Ring and Wahlberg6]. The research of electromagnetic field in plasma is related to accelerator physics, high-energy density physics, inertial confinement fusion, and astrophysics phenomena [Reference Tajima and Dawson7Reference Ng, Ao, Perrot, Dharma-Wardana and Foord12]. In the past several years, many methods based on charged particle radiography have been tried, such as laser wake field accelerator electron radiography, monoenergetic electron radiography, and monoenergetic proton radiography [Reference Schumaker, Nakanii and McGuffey13Reference Chen, Li and Chen19]. In this paper, we demonstrate a new method to achieve continuous point measurement for the electromagnetic field strength.

As a diagnosis probe, high-energy electron has some advantages for the transient electromagnetic field measuring. Relativistic speed beams are taken easily by making the electrons penetrate specimen with millimeter size in several tens of picoseconds; compared with the other relativistic particles, electron has lower magnetic rigidity, which makes it more sensitive to the electromagnetic field; besides, ultrashort bunch is taken easier, to ensure the quasistatic of diagnosed specimen.

High-energy electron radiography (HEER) has been developed at LANL, Tsinghua University and Institute of Modern Physics, Chinese Academy of Science, in the past several years [Reference Merrill, Harmon and Hunt20Reference Zhou, Fang and Chen26]. The several microns spatial resolution has been also taken in the experiment. In the past years, only static target or fluid target has been used as the object in HEER experiment. Up to now, there is no report of using the point-to-point HEER as the electromagnetic field diagnosis. In this paper, a new method is proposed that is based on HEER beam line design for magnetic field area diagnosis.

2. Principle

Above all, two approximates can ensure the accuracy of this diagnosis. Firstly, the electric field is very similar to electrostatic field in the plasma. Thence, for the process from infinity to infinity, all the incident and exit potential of probe beams are zero, and there is no energy decrease or increase when the electron beam has penetrated the system. Secondly, for the scattered electron beams, the E/B field area is filled with very small amount of materials to intervene the electron scattering angle, just like the ultrashort intense laser-foil interaction process [Reference Chen, Li and Chen19].

The whole diagnosis process is divided into two parts to describe the interaction of beam line with plasma and the electrons transport in the point-to-point HEER beam line.

For the first subprocess, high-energy electron beams will be deflected by a magnetic field when penetrating the system. The deflection can be described by the following formula:

(1) θ = ω d t = e B d t γ m 0 = e B γ m 0 c d z ,

where

(2) γ = 1 1 v 2 / c 2 ,

where θ is deflection of electron beam, ω is angular velocity of electrons in magnetic field, v is velocity of electrons, m 0 is the electron rest mass, c is speed of light in vacuum. B is the weight of magnetic vector at x-y plane, and z is the position of magnetic area.

Based on the above description, if the incident electrons have a specific angle distribution with high symmetry in polar coordinate at x-y plane, there is one-to-one correspondence between transmittance and deflection.

The angle distribution of monoenergtetic electron interacting with matter can be described by the following function:

(3) f ϕ = N t , ϕ N 0 = 1 ϕ 0 t 2 π e 1 / 2 ϕ / ϕ 0 t 2 ,

where

(4) ϕ 0 t = 13.6 MeV β c p t 1 + 0.038 ln t ,

where ϕ is scattered angle of electrons, t = X / X 0 , X is the thickness of target, and X 0 is the radio length of specimen materials.

From formula (3), after interactions between the incident electron and target, the electron beams will have a specific angle distribution. And the distribution should have high symmetry in polar coordinate. In other words, the angle distribution of incident electrons can be controlled by scattering target so as to meet diagnostic demand.

The next step is deflection measured by HEER beam line. For monoenergetic electron beams, the transport in beam line can be explained by the following matrix:

(5) x i x i y i y i = R 11 R 12 0 0 R 21 R 22 0 0 0 0 R 33 R 34 0 0 R 43 R 44 x 0 x 0 y 0 y 0 ,

where xi, yi and x i , y i are the position and angle of electrons at the observation plane, and Rij are the conversion factor of the beam line. The x 0, y 0 and x 0 , y 0 are the position and angle of electrons at the emission plane [Reference Brown27].

At the image plane, transport matrix parameters R 12 = R 34 = 0. It means that the electron position at the image plane is irrelevant with the angle of electrons at the object plane. This beam line design is called point-to-point radiography. Between the image plane and the object plane, by optimizing, there will be a plane named Fourier plane which matches the transport matrix parameters R 11 = R 33 = 0. It means that the electron angle information at object plane has been translated to position information at this plane. Thence, an aperture at the Fourier plane can achieve angle selection for transmitted electrons. In the past years, the application of aperture is to get better spatial and areal density resolutions. Now, the magnetic strength diagnosis depends on the characteristics of the aperture.

The aperture should be set at the Fourier plane where aperture can select the angle around the center axis when the electrons are not deflected. If the electron beam collective is deflected by the magnetic field, the angle selection will also be deflected from the center axis of angle distribution. Thence, for the incident electrons with specific angle distribution, the deflection of them has a negative correlation with its transmittance. Furthermore, it is necessary to make the ratio of the x-half-axis and y-half-axis equal R12F/R34F to ensure one-to-one correspondence between magnetic strength and transmittance. The footnote F means that the transport matrix parameters are from the object plane to Fourier plane. The principle is shown in Figure 1.

Figure 1: (color online). Schematic diagram of HEER for magnetic area diagnosis. (a) The angle distribution of incident electrons. (b) The electrons angle distribution after scattering target. (c) The electron position at Fourier plane; the green shadow area is the aperture position.

3. Simulations

3.1. General Setup

The sketch of integral simulation is shown in Figure 2. The incident electrons are scattered by an aluminum foil initially, and then, the scattered electrons penetrate the magnetic vacuum. Then, HEER magnetic lens are set to transport, select, and refocus the electrons behind target. Finally, the electron number density will be counted by the detector at image plane.

Figure 2: (color online). Schematic of simulation design. The magnetic area as the specimen is a quadrupole magnet (a). And the aperture is designed as an ellipse, where x-half-axis is 1 mm and y-half-axis is 0.5 mm in length (b).

3.2. Image Lens Optimization

The typical charged particle image beam line should satisfy that the transport matrix parameters are R 12 = R 34 = 0 at the image plane. But for the force field diagnosis HEER, as mentioned in Section 2, it is necessary to make the x-axis and y-axis Fourier plane coincident run along the z-axis. Under this requirement, the imaging lens system adapting 50 MeV kinetic energy electron beams is optimized by COSY INFINITY 9.1 [Reference Berz and Makino28]. It includes eight quadrupole magnets, as shown in Figure 2; the length of them is 10 cm, the inner diameter is 40 mm, and the MG of QA is 3.9097 T/m, and QB is -3.6295 T/m. The drift length L1 is 30 cm, and L2 is 10 cm. The total length of this beam line is 2.6 m. The optimization result is shown in Figure 3. And the relational transport matrix parameters of it are shown in Table 1.

Figure 3: Electron beam trace from object plane to image plane in the x-plane and y-plane.

Table 1: The transport matrix parameters of radiography beam line.

According to transport matrix parameters from the object plane to Fourier plane, the aperture in the simulation is designed as an ellipse shape as shown in Figure 2(b) and the corresponding selection angle range can be described by the following formula:

(6) x 0 2 + y 0 2 0.91 mrad 2 .

3.3. Specimen Design

The specimen is composed of scattering target and magnetic vacuum. In this work, we select a 5 μm thick aluminum foil as the scattering target. On the one hand, as a low Z element, it can ensure that the probe electrons have lower energy spread. On the other hand, aluminum is always selected as the target material in the research of intense laser-solid interaction or Z-pinch. Combined with the aperture selection, the transmittance corresponding to deflection is shown in Figure 4.

Figure 4: Angle distribution of scattered electrons.

For this Gaussian distribution, we delimit the transmittance larger than 0.01 as detectable. That means the detection range of deflection is from -3 mrad to 3 mrad. For 50 MeV electrons, the corresponding magnetic strength diagnostic range is from -0.51 Tmm to 0.51 Tmm.

Except for the lens design, there are two factors that might influence measuring accuracy in this design: deflection and magnetic gradient (MG) of the specimen. The deflection can be limited by the incident electron energy. To get microspatial resolution, we should control the deflection less than 10 mrad for 1 mm scale expansion size. To study the influence of MG on measurement accuracy, we select a quadrupole model as the magnetic vacuum in this simulation, and a group of MG is set as 1, 2, and 3 T/mm.

3.4. Complete Simulation Process

We simulate the situation that the line beam along the x-axis and y-axis penetrates the specimen. This set has two advantages. Firstly, the focusing and defocusing influences can be analyzed, respectively; secondly, the spatial resolution along the x-axis and y-axis also can be self-governed. The whole simulation of diagnostic process includes three sections: incident electrons interact with scattering target, electron beams go through the area with electromagnetic field, and electrons are refocused by HEER beam line. For the first simulation section, EGS5 codes are selected to do this [Reference Hirayama, Namito, Bielajew, Wilderman and Nelson29]. Because the magnetic field model is the standard quadrupole field as the specimen, the last two section simulation is done by PARMELA software [Reference Young30].

4. Results and Discussion

In the case of specimen with no magnetic vacuum, the scattered electron angle distribution and position distribution at Fourier plane are counted. The statistical steps of angle distribution are 0.04 mrad along x and y and of position are 0.044 mm along the x-axis and 0.021 mm along y-axis, respectively. The results are shown in Figure 5.

Figure 5: (color online). The angle distribution of electrons after scattering target (a) and the position distribution of electrons at the Fourier plane (b).

According to Figure 5, we verify that the angle distribution after scattering target is translated to position distribution at Fourier plane and the convert ratios correspond to R 12F and R 34F along the x-axis and y-axis, respectively.

Figure 6 shows the electron position distribution at the Fourier plane when different magnetic field gradients of specimen magnetic are set. Compared with Figure 5, the electron distribution at the Fourier plane is deformed. The distribution is broadened along the direction of Lorentz force in the magnetic field. The size of line beam broadening is related with the magnetic gradient. In this case, the transmittance will be also different when the same aperture is used in the simulation.

Figure 6: The electron position distribution at the Fourier plane under different specimen quadrupole designs.

We integrate the two line beams into a crossing beam as a probe electron beam, and the diagnosis results for the quadrupole magnetic field with different magnetic gradients are shown in Figure 7. Based on the distribution of incident angle distribution, the range of diagnosis is from -0.51 Tmm to 0.51 Tmm. Corresponding to different magnetic gradient settings, the range is from -0.51 mm to approximately 0.51 mm, -0.26 mm to approximately 0.26 mm, and -0.17 mm to approximately 0.17 mm. In Figure 7, the simulation results are very consistent with the theoretical value regardless of the magnetic focusing or defocusing interactions and a little deviation in the measurement at the weak field area. That means, at the edge of the magnetic area, there might be deviation in the experiment.

Figure 7: (color online). Simulation results under different designs for quadrupole magnetic field as specimens.

The spatial resolution can be taken by the analysis of the line beam broadening at the image plane. The statistical result of electron distribution at image plane is shown in Figure 8.

Figure 8: (color online). The distribution of electrons at image plane in different specimen quadrupole designs.

And the following analysis results are shown in Table 2.

Table 2: The RMS spatial resolution along the x-axis and y-axis.

The simulation results indicate that the RMS spatial resolution of this design is better than 4 micrometers along the x-axis and y-axis. And the distribution of the magnetic strength field taken by this method is continuous. In fact, for the smaller size specimen, the spatial resolution can be also improved by cascade magnification HEER so as to get more delicate structure.

5. Conclusions

We present a new method to diagnose the transient magnetic field that is based on the HEER beam line design. The simulation results of 50 MeV penetrating the quadrupole model indicates that this method has high accuracy for strong field measurement no matter whether the magnetic gradient interaction is focusing or defocusing. At the same time, spatial resolution better than 4 micrometers is also got in our simulations. Of course, smaller aperture application or more optimized beam line design can get better spatial resolution. In summary, these results indicate that this method is very suitable for the delicate diagnosis of the transient magnetic field strength.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare that there is no conflict of interest regarding the publication of this paper.

Acknowledgments

This work is supported by the National Key R&D Program of China under Grant (No. SQ2019YFA040016).

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Figure 0

Figure 1: (color online). Schematic diagram of HEER for magnetic area diagnosis. (a) The angle distribution of incident electrons. (b) The electrons angle distribution after scattering target. (c) The electron position at Fourier plane; the green shadow area is the aperture position.

Figure 1

Figure 2: (color online). Schematic of simulation design. The magnetic area as the specimen is a quadrupole magnet (a). And the aperture is designed as an ellipse, where x-half-axis is 1 mm and y-half-axis is 0.5 mm in length (b).

Figure 2

Figure 3: Electron beam trace from object plane to image plane in the x-plane and y-plane.

Figure 3

Table 1: The transport matrix parameters of radiography beam line.

Figure 4

Figure 4: Angle distribution of scattered electrons.

Figure 5

Figure 5: (color online). The angle distribution of electrons after scattering target (a) and the position distribution of electrons at the Fourier plane (b).

Figure 6

Figure 6: The electron position distribution at the Fourier plane under different specimen quadrupole designs.

Figure 7

Figure 7: (color online). Simulation results under different designs for quadrupole magnetic field as specimens.

Figure 8

Figure 8: (color online). The distribution of electrons at image plane in different specimen quadrupole designs.

Figure 9

Table 2: The RMS spatial resolution along the x-axis and y-axis.