Quartz modification by Zn ion implantation and swift Xe ion irradiation

Physica Status Solidi (c) Pub Date : 2017-06-06 DOI:10.1002/PSSC.201700112

V. Privezentsev, V. Kulikauskas, A. Didyk, V. Skuratov, E. Steinman, A. Tereshchenko, N. N. Kolesnikov, A. Trifonov, O. Sakharov, S. Ksenich

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Abstract

The quartz slides were implanted by 64Zn+ ions with dose of 5 × 1016/cm2 and energy of 100 keV. After implantation, the amorphous metallic Zn nanoparticles with an average radius of 3.5 nm were created. The sample surface becomes nonuniform, its roughness is increased and its values rise up to 6 nm compared to virgin state, and the roughness maximum is at a value of about 0.8 nm. The surface is made up of valleys and hillocks which have a round shape with an average diameter about 200 nm. At the center of these hillocks are pores with a depth up to 6 nm and a diameter of about 20 nm. After implantation in UV-vis diapason, the optical transmission decreases while PL peak (apparently due to oxygen deficient centers) at wavelength of 400 nm increases. Then the samples were subjected to swift Xe ion irradiation with the fluences of 1 × 1012–7.5 × 1014/cm2 and energy of 167 MeV. After Xe irradiation, the sample surface roughness shat down to values of 0.5 nm and the roughness maximum is at a value of about 0.1 nm. Optical transmission in UV-vis diapason increases. The PL peak at wavelength of 400 nm is decreased while a PL peak at wavelength of 660 nm is raised. This peak is presumably due to non-bridging oxygen hole centers or/and NPs with structure Si(core)/SiO2(shell). HRTEM image of Zn-implanted quartz subsurface layer. One can see the Zn amorphous nanoparticles, which confirms the electron diffraction pattern (insert).

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Zn离子注入和快速Xe离子辐照改性石英

用64Zn+离子注入石英玻片，剂量为5 × 1016/cm2，能量为100 keV。注入后，得到了平均半径为3.5 nm的非晶金属锌纳米颗粒。样品表面变得不均匀，粗糙度增加，与未加工状态相比，粗糙度值上升至6 nm，粗糙度最大值约为0.8 nm。表面由山谷和丘陵组成，它们的形状为圆形，平均直径约为200纳米。在这些小丘的中心是深度达6纳米，直径约20纳米的孔隙。紫外-可见介质注入后，光透射率下降，400 nm处的PL峰增加(明显是由于缺氧中心)。然后对样品进行1 × 1012-7.5 × 1014/cm2的快速氙离子辐照，能量为167 MeV。经过Xe辐照后，样品表面粗糙度降至0.5 nm左右，粗糙度最大值约为0.1 nm。紫外-可见介质的光传输增加。400 nm处的发光峰降低，660 nm处的发光峰升高。这个峰值可能是由于非桥接氧孔中心或/和具有Si(核)/SiO2(壳)结构的NPs。浸锌石英亚表面层HRTEM图像。可以看到锌非晶纳米颗粒，这证实了电子衍射图(插入)。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Physica Status Solidi (c)

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