11 MeV能损型质子照相空间分辨能力模拟

卢亚鑫; 李一丁; 魏涛; 杨国君; 张开志; 龙全红; 马超凡

doi:10.11884/HPLPB201830.170414

11 MeV能损型质子照相空间分辨能力模拟

doi: 10.11884/HPLPB201830.170414

中国工程物理研究院流体物理研究所, 四川绵阳 621900

基金项目:

国家自然科学基金项目 11405162

国家自然科学基金项目 11475157

国家自然科学基金项目 11405161

国家自然科学基金项目 11375162

中国工程物理研究院院长基金项目 201402086

中国工程物理研究院发展基金项目 2014A0402016

详细信息

作者简介:
卢亚鑫(1993-)，男，硕士，从事带电粒子辐射成像技术研究；luyaxin2013@163.com

通讯作者:
李一丁(1983—)，男，博士，从事加速器及带电粒子成像技术研究；li_yi_ding@qq.com

中图分类号: O59
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出版历程
- 收稿日期: 2017-10-29
- 修回日期: 2017-12-27
- 刊出日期: 2018-06-15

Simulation of imaging ability of 11 MeV proton radiography with energy-loss imaging lens

Institute of Fluid Physics, CAEP, P.O.Box 919-106, Mianyang 621900, China

摘要

摘要: 透射质子的能损和散射角是质子照相成像模糊的主要来源。基于Zumbro聚焦成像磁透镜的质子照相技术，可基本消除散射角引起的成像模糊，实现几十μm的空间分辨，但无法对能损信息进行优化是其空间分辨能力难以进一步提升的主要原因。为利用透射质子的能损信息，进一步提高质子照相的空间分辨能力，提出了一种新型的成像磁透镜，称之为能损型聚焦成像磁透镜。基于11 MeV低能能损型质子照相的实验束线和Geant4模拟软件，建立全过程照相模型，研究11 MeV能损型成像束线的空间分辨能力。模拟研究表明：对于10 μm厚的Al箔，考虑点扩散函数等测量系统成像模糊的影响，11 MeV能损型成像束线可实现约30 μm的空间分辨。与等大型Zumbro磁透镜相比，空间分辨能力得到显著提升。
- Zumbro磁透镜 /
- 能损型成像束线 /
- Fourier平面 /
- 空间分辨能力
Abstract: Energy loss and scattering angle of penetrating protons are main sources of image blur for proton radiography (PRAD). PRAD relying on Zumbro lens can basically eliminate the image blur caused by scattering angle and achieve spatial resolution of several tens microns. However, the chromatic blur resulted from energy loss cannot be optimized, and it is the major cause for limiting spatial resolution. To eliminate the influence of energy loss and make a further improvement of spatial resolution, a new type of magnetic lens is proposed, called energy-loss focused imaging lens. A 11 MeV low-energy energy-loss imaging beamline is designed and a numerical model is built for energy-loss PRAD by using GEANT4 to study its image ability in simulation. The simulation results show that the 11 MeV low-energy energy-loss PRAD can achieve about 30 μm spatial resolution for 10 μm Al target. Compared with Zumbro lens of the same size, the spatial resolution is improved obviously.
- Zumbro lens /
- energy-loss imaging lens /
- Fourier plane /
- spatial resolution

HTML全文

图 1 11 MeV能损型成像束线布局示意图

Figure 1. Sketch of 11 MeV energy-loss imaging beam line

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图 2 11 MeV质子经过不同厚度Al膜后的能量分布曲线和散角分布曲线

Figure 2. Energy spectrum and distribution of scattering angle when 11 MeV protons pass through different Al foils

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图 3 磁透镜成像模糊随厚度的变化曲线

Figure 3. Curve of image blur through thickness

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图 4 测试样品示意图及模拟结果

Figure 4. Actual picture and simulation result of reticle object (W denotes the width of strips and D denotes the distance between two adjacent strips)

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图 5 图 4(b)中虚线位置对应的微分曲线

Figure 5. Differential curve on dotted line in Fig. 4(b)

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表 1 11 MeV能损型聚焦成像磁透镜参数

Table 1. Detailed parameter of 11 MeV energy-loss magnetic lens

parameter	value	parameter	value
M₁₂(at the energy Fourier plane(EFP))	-0.299 mm/mrad	M₁₆(at the EFP)	611.44 m
R₁₂₆ (at the image plane)	2.912 m	R₁₆₆ (at the image plane)	-385.3 m
bending radius of dipoles	1 m	bending angle of dipoles	45°
drift space(first five)	0.8, 0.5, 0.5, 0.4, 0.4 m	quadrupole length(first three)	0.15, 0.1, 0.1 m
bending gradients	4.806 kg	quadrupole gradients (first three)	72.234, -73.343, 56.692 kg·m^-1
total length	7.4705 m	beam pipeline radius	25 mm

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参考文献(11)

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