Journal of Radiation Research and Radiation Processing, Volume. 40, Issue 5, 050101(2022)
Progress in the research on radiation-induced defects in nanomaterials
Fig. 1. TID-induced changes at the interface layer: (a) optical absorption spectra of the pristine and irradiated a-SiO2/Si interface, together with those of bulk SiO, Si and SiO2 for comparison; (b) the changes of band gaps of the ultra-thin films at different doses; (c) H distributions of samples irradiated at different doses obtained from sims (the r0, r3, r6, r12 and r24 labels mean that the films were irradiated to 0, 3, 6, 12 and 24 kGy; the original text using r0, r0.3, r0.6, r1.2, and r2.4 labels mean the films were irradiated to 0, 0.3, 0.6, 1.2 and 2.4 Mrad before sims measurements); (d) the O/Si ratios increase and H/Si ratios decrease with the increasing doses; (e) changes in the percentages of different chemical states of Si at different doses; (f) the distribution of O atom across the interface (green line), and gamma-ray irradiation-induced changes[5] (color online)
Fig. 2. (a) Annealing of defects induced by radiation of Ar ions: ○/● stands for the number of C atoms with one coordination before/after annealing; □/■ stands for the number of two-coordinated atoms before/after annealing; △ correspond to the number of sputtered C atoms; (b, c) schematic illustration of defects before and after annealing[20]
Fig. 3. N atom doping in graphene by co-irradiation with precursors[32]
Fig. 5. Defects and adsorption performance of zeolite prepared by radiation[54]
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Pingping GAN, Xianmei CHEN, Zhiwen JIANG, Yunlong WANG, Jun MA. Progress in the research on radiation-induced defects in nanomaterials[J]. Journal of Radiation Research and Radiation Processing, 2022, 40(5): 050101
Category: Research Articles
Received: Mar. 19, 2022
Accepted: May. 24, 2022
Published Online: Nov. 3, 2022
The Author Email: WANG Yunlong (wylong@nuaa.edu.cn)