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针对准单色近平行光束X射线背光成像诊断需求,提出了一种用球面弯晶进行X射线衍射选单从而获取准直光束的新方案.在神光Ⅱ装置上,设计了基于球面弯晶X射线衍射选单准直光束系统,完成了该系统的安装、调试和实验应用,获得了准单色(10-3<△λ/λ <10-2)、小发散角(< 2 mrad)和大辐照匀斑(直径φ 500 m)的X射线光源.同时基于衍射光学和球面镜成像理论,研究了不同布拉格角对球面弯晶X射线衍射光束发散角及其像散差的影响.结果表明,布拉格角会影响球面弯晶X射线衍射光束的发散角.用控制布拉格角范围的方法有望获得发散角优于1 mrad的近平行光束X射线光源.这种准单色、极小发散度和均匀角分布的X射线光源可应用于高分辨X射线成像诊断.In inertial confined fusion experiments, an excellent-performance and high-efficiency X-ray source plays an important role in X-ray radiography schemes. Indeed, it can be used in a variety of X-ray experimental techniques. The mono-chromaticity, flux intensity, degree of collimation (the radiation can be transported long distances without loss), and spot size of the X-ray source affect the quality of imaging. Ray-tracing simulations, which are validated by experimental results, demonstrate that high-intensity collimated X-ray beams can be produced from an isotropic X-ray source. Therefore, a method of improving the performance of an X-ray source from a laser-produced plasma is presented. A spherically bent crystal is used to collimate mono-chromatic X-rays emitted from a laser-produced plasma. Here we design a spherically bent crystal spectrometer system for collimating the laser-produced X-rays. The system performance is experimentally tested at the Shenguang Ⅱ (SGⅡ) laser facility located in Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Sciences. The beam divergence is measured by using a metal grid placed downstream from the crystal, the metal grid that possesses wires with 60 μm in diameter and 127 μm in period. An imaging plate (IP) is placed at various distances downstream from grid. The quality of the generated beam is monitored by measuring the dimensions of the grid image formed by the beam on IP. While the narrow range of wavelength is measured with a spherically bent crystal spectrometer. Experimental results show that the spherically bent crystal spectrometer system can produce quasi-monochromatic (10-3 < △ λ/λ <10-2) X-ray beams with a high degree of collimation (less than 2 mrad divergence), uniform spot size (~500 μm), and a relative tenability in the wide spectral range. The influences of various experimental parameters on the quality of beam collimation are evaluated in two ways. They can be investigated in test experiments by representing the beam divergence distribution as a function of Bragg angle. In another study of the effect of the aberrations, when the incident beam on the spherically bent crystal is not normal, the beam is less collimated in the tangential plane, and out of collimation in the sagittal plane. Following the ray-tracing method, we analyze the diffracted beam divergence produced by the astigmatic aberration. The qualitative conclusion is that the good agreement with the experimental results is obtained. By fully utilizing limited Bragg angle range, the spherically bent crystal spectrometer system can realize collimated diffracted X-ray beams with divergence of less than 1 mrad by using a laser-produced plasma X-ray source under the appropriately experimental parameters.
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Keywords:
- X-ray source /
- monochromatic diffraction /
- collimated beams
[1] Zhao Z Q, He W H, Wang J, Hao Y D, Cao L F, Gu Y Q, Zhang B H 2013 Chin. Phys. B 22 104202
[2] Lang J C, Srajer G, Wang J, Lee P L 1999 Rev. Sci. Instrum. 70 4457
[3] Babacar D, Vu Thien B 2012 Rev. Sci. Instrum. 83 094704
[4] Li F Z, Liu Z G, Sun T X 2016 Rev. Sci. Instrum. 87 093106
[5] Henke B L, Gullikson E M, Davis J C 1993 At. Data Nucl. Data Tables 54 181
[6] Chen J P, Wang J Y, Zou J, Lü H Y, Hu X D, Xu Y 2017 Nucl. Instrum. Meth. A 870 19
[7] Wilklns S W, Stevenson A W 1988 Nucl. Instrum. Meth. A 269 321
[8] Protopopov V, Shishkov V A, Kalnov V A 2000 Rev. Sci. Instrum. 71 4380
[9] Wilkins S B, Spencer P D, Hatton P D, Tanner B K, Lafford T A, Spence J, Loxley N 2002 Rev. Sci. Instrum. 73 2666
[10] Korotkikh E M 2006 X-Ray Spectrom. 35 116
[11] Hray J, Oberta P 2008 Rev. Sci. Instrum. 79 073105
[12] Nishikino M H, Sato K S, Hasegawa N, Ishino M H, Ohshima S S, Okano Y, Kawachi T Y, Numasaki H, Teshima T, Nishimura H 2010 Rev. Sci. Instrum. 81 026107
[13] Sanchez del Rio M, Fraenkel M, Zigler A, Faenov A Ya, Pikuz T A 1999 Rev. Sci. Instrum. 70 1614
[14] Gerritsen H C, van Brug H, Bijkerk F, van der Wiel M J 1986 J. Appl. Phys. 59 2337
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[1] Zhao Z Q, He W H, Wang J, Hao Y D, Cao L F, Gu Y Q, Zhang B H 2013 Chin. Phys. B 22 104202
[2] Lang J C, Srajer G, Wang J, Lee P L 1999 Rev. Sci. Instrum. 70 4457
[3] Babacar D, Vu Thien B 2012 Rev. Sci. Instrum. 83 094704
[4] Li F Z, Liu Z G, Sun T X 2016 Rev. Sci. Instrum. 87 093106
[5] Henke B L, Gullikson E M, Davis J C 1993 At. Data Nucl. Data Tables 54 181
[6] Chen J P, Wang J Y, Zou J, Lü H Y, Hu X D, Xu Y 2017 Nucl. Instrum. Meth. A 870 19
[7] Wilklns S W, Stevenson A W 1988 Nucl. Instrum. Meth. A 269 321
[8] Protopopov V, Shishkov V A, Kalnov V A 2000 Rev. Sci. Instrum. 71 4380
[9] Wilkins S B, Spencer P D, Hatton P D, Tanner B K, Lafford T A, Spence J, Loxley N 2002 Rev. Sci. Instrum. 73 2666
[10] Korotkikh E M 2006 X-Ray Spectrom. 35 116
[11] Hray J, Oberta P 2008 Rev. Sci. Instrum. 79 073105
[12] Nishikino M H, Sato K S, Hasegawa N, Ishino M H, Ohshima S S, Okano Y, Kawachi T Y, Numasaki H, Teshima T, Nishimura H 2010 Rev. Sci. Instrum. 81 026107
[13] Sanchez del Rio M, Fraenkel M, Zigler A, Faenov A Ya, Pikuz T A 1999 Rev. Sci. Instrum. 70 1614
[14] Gerritsen H C, van Brug H, Bijkerk F, van der Wiel M J 1986 J. Appl. Phys. 59 2337
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