X射线荧光全息术中入射能量对原子像的影响

谢红兰; 陈建文; 高鸿奕; 熊诗圣; 李儒新; 徐至展

光学学报, 2004, 24 (7): 1004, 网络出版: 2010-05-25

X射线荧光全息术中入射能量对原子像的影响

Influence of Incident Energy on Reconstructed Atomic Images in X-Ray Fluorescence Holography

论文大纲

谢红兰陈建文高鸿奕熊诗圣李儒新徐至展

作者单位

中国科学院上海光学精密机械研究所, 上海 201800

X射线荧光全息术同步辐射晶体结构傅里叶变换 X-ray fluorescence holography synchrotron radiation crystal structure Fourier transform

摘要

X射线荧光全息术是一种新型的显微成像技术，它能在原子水平上直接观察到晶体内部的三维结构。然而它所得到的原子像存在明显的孪生像现象。因此，采用多重能量的全息记录来消除孪生像。分别以单个和多个铁原子为模型，数值模拟了它们在4π立体角范围内、不同范围的入射能量的情况下记录的全息图。比较由这些全息图重构得到的原子像，发现入射能量范围越宽，其消除孪生像的效果越好，而且随着入射能量的提高，其原子像的分辨力也越高。

Abstract

X-ray fluorescence holography is a novel microscopic imaging method, which can provide the information of three-dimensional atomic arrangement in a single crystal. However, obvious twin images apperar on the cetomic images dotained by this method. Therefore, the method called “multiple-energy X-ray hologrophy” that images reconstructed from holograms recorded at several incident energies are combined properly is used to remove the twin images. In this work, a single Fe atom and multi Fe atoms as model respectively, holograms recorded in a complete 4π solid angle with different range and magnitude of incident energies are calculated. Compared reconstructed atomic images from these holograms, it is found that the wider range of incident energies, the better effect of removing twin images is. Moreover, the difference between simulated peak positions and actual atomic positions decreases and the resolution of reconstructed atomic images increases with increasing incident energy.

参考文献

[1] Jiang Shiping, Zhang Yuxuan, Zhang Xinyi et al.. Soft X-ray microscopy of wet samples in helium environment. Acta Optica Sinica (光学学报), 2000, 20(1): 142～144 (in Chinese)

[2] Zhu Peiping, Gao Hongyi, Jiang Shiping et al.. X-ray image holography. Acta Optica Sinica (光学学报), 2001, 21(7): 850～852 (in Chinese)

[3] Xie Honglan, Gao Hongyi, Chen Jianwen et al.. A method of eliminating scattered light in X-ray fluorescent tomography. Acta Optica Sinica (光学学报), 2003, 23(4):385～389 (in Chinese)

[4] Jacobsen C, Chapmen H N, Kirz J et al.. Biological microscopy and soft X-ray optics at stony brook. J. Elect. Spect. and Related Pheno., 1996, 80(5):337～341

[5] Wang Yuxin, Jacobsen Chris. A numerical study of resolution and contrast in soft X-ray contact microscopy. http: //xray1.physics.sunysb.edu/～jacobsen

[6] Gabor D. A new microscopic principle. Nature, 1948, 161(5):777～778

[7] Szke A. X-ray and electron holography using a local reference beam. in Short Wavelength Coherent Radiation: Generation and Applications, edited by T. Atwood and J. Boker, AIP Conf. Proc. 147 (AIP, New York), 1986. 361～367

[8] Len P M, Gog T, Fadley C S et al.. X-ray fluorescence holography and multi-energy X-ray holography: a critical comparison of atomic images. Phys. Rev. B, 1997, 55(6): R3323～R3327

[9] Tegze M, Faigel G. X-ray holography with atomic resolution. Nature, 1996, 380(3):49～51

[10] Adams B, Novikov D V, Hiort T et al.. Atomic holography with X-rays. Phys. Rev. B, 1998, 57(13):7526～7534

[11] Tegze M, Faigel G, Marchesini S et al.. Three dimensional imaging of atoms with isotropic 0.5 resolution. Phys. Rev. Lett., 1999, 82(24):4847～4850

[12] Marchesini S, Schmithüsen F, Tegze M et al.. Direct 3D imaging of Al70.4Pd21Mn8.6 quasicrystal local atomic structure by X-ray holography. Phys. Rev. Lett., 2000, 85(22):4723～4726

[13] Spence J. Holograms of atoms. Nature, 2001, 410(4):1037～1040

[14] Kopecky M, Lausi A, Busetto E et al.. X-ray absorption holography. Phys. Rev. Lett., 2002, 88(18):185503-1～185503-3

[15] Kopecky M, Busetto E, Lausi A et al.. Recording of X-ray holograms on a position-sensitive detector. Phys. Rev. Lett., 2001, 78(19):2985～2987

[16] Xie Honglan, Gao Hongyi, Chen Jianwen et al.. Numerical simulation study for atomic-resolution X-ray fluorescence holography. Acta Physica Sinica (物理学报)， 2003， 52(9)：2223～2229 (in Chinese)

[17] Xie H L, Chen J W, Gao H Y et al.. X-ray fluorescence holography, ISTM/2003 5th International Symposium on Test and Measurement Vol. 5, 3703～3706

[18] Xie H L, Chen J W, Gao H Y et al.. A method of improving spatial resolution in X-ray fluorescence holography. Optik, 2003, 114(7): 317~321

[19] Faigel G, Tegze M. X-ray holography. Rep. Prog. Phys., 1999, 62:355～393

[20] Born M, Wolf E. Principles of Optics. London: Pergamon, 1959

[21] Barton J J. Photoelectron holography. Phys. Rev. Lett., 1988, 61(12):1356～1359

[22] Barton J J. Removing multiple scattering and twin images from holographic images. PHys. Rev. Lett., 1991, 67(22):3106～3109

谢红兰, 陈建文, 高鸿奕, 熊诗圣, 李儒新, 徐至展. X射线荧光全息术中入射能量对原子像的影响[J]. 光学学报, 2004, 24(7): 1004. Xie Honglan, Chen Jianwen, Gao Hongyi, Xiong Shisheng, Li Ruxin, Xu Zhizhan. Influence of Incident Energy on Reconstructed Atomic Images in X-Ray Fluorescence Holography[J]. Acta Optica Sinica, 2004, 24(7): 1004.

X射线荧光全息术中入射能量对原子像的影响

关于本站 Cookie 的使用提示

全站搜索

X射线荧光全息术中入射能量对原子像的影响

相关论文

相关资讯

关于本站 Cookie 的使用提示

全站搜索