双离子(40Ar+,C2H6+)辐照合成金刚石纳米晶颗粒

用双离子(40Ar+,C1H6+)辐照实验完成了从多壁碳纳米管向金刚石纳米晶颗粒的转变.对转变机理进行了初步探讨.这一探索有望能成为一种金刚石纳米晶合成的新途径.由此可知,多重荷能离子辐照用于其他材料纳米结构的制备也不是凭空设想.     

C20富勒烯的Ar+离子辐照合成

Ar⁺离子辐照聚乙烯靶表面在室温情况下合成的C₂₀,已采用高分辨率透射电子显微镜/电子衍射装置、飞行时间质谱、红外和拉曼谱仪进行了研究.结果认为,辐照诱发的微晶体由笼式C₂₀组成. 关键词：     

内质网应激对碳离子辐照宫颈癌HeLa 细胞的影响

利用不同剂量的碳离子辐照二硫苏糖醇(2.5 mmol/L) 预处理的HeLa 细胞,探讨了内质网应激反应对碳离子辐照宫颈癌HeLa 细胞的影响。实验发现:与单独辐照组相比,二硫苏糖醇联合碳离子辐照后细胞的存活率下降,而凋亡率增加;二硫苏糖醇联合碳离子辐照加重了碳离子辐照引起的细胞周期阻滞;且联合辐照组的自噬被明显激活。结果表明,持续的内质网应激可改变宫颈癌HeLa 细胞对碳离子辐照反应,且二硫苏糖醇可能通过影响HeLa 细胞的自噬性细胞死亡通路发挥作用。To investigate the effect of endoplasmic reticulum stress on HeLa cells to 12C6+ ion irradiation,HeLa cells were pretreated with 2.5 mmol/L dithiothreitol and irradiated by 12C6+ ions with different doses.The results showed that, compared with IR alone, dithiothreitol combined with carbon ion irradiation caused HeLa cell survival decreased, and the apoptosis increased. Moreover, dithiothreitol and carbon ion radiation combination treatment led to a significant increase of G2/M phase, and autophagy was activated obviously in combination treatment group. The results imply that continuous endoplasmic reticulum stress can change the response of HeLa cells to 12C6+ irradiation, and dithiothreitol may affect HeLa cells through the autophagy cell death pathway.     

离子辐照石墨生成的纳米尺寸Ar泡

用60keV的Ni⁺和Ar⁺在相同实验条件下,先后分别辐照同一块石墨靶,剂量均为10¹⁸/cm².带能量色散X射线分析和电子衍射分析的高分辨透射电子显微镜观察和分析发现,尺寸不同的纳米Ar泡嵌在类玻璃碳薄片中,部分泡内的Ar可能已形成固体结构.     

离子辐照聚乙烯合成小于C60的富勒烯分子晶体

通过荷能离子（包括团簇离子）辐照聚乙烯首次合成了小于C60的富勒烯－C20和C26分子晶体。在此基础之上，进一步探索其他小富勒烯分子晶体（如C32，C38和C24）存在的确凿证据。     

铅离子对碳纳米颗粒荧光发射规律的影响

以热解石墨为原料,利用电化学方法,制备了荧光碳纳米颗粒。系统地研究了在不同浓度、时间、pH值、温度等条件下,Pb2+离子对碳纳米颗粒荧光发射规律的影响。实验结果表明:Pb2+离子不改变光谱形状,但可以降低荧光峰值强度;Pb2+离子作用荧光碳纳米颗粒的时间越长,猝灭效率越低;pH值不同,猝灭效率不同;随着温度的升高,Pb2+离子对碳纳米颗粒荧光的猝灭效率逐步提高。其猝灭机理可能为电荷转移猝灭和动态猝灭。     

纳米金属掩膜和离子辐照技术制备高温超导约瑟夫森结

研究了一种利用纳米金属掩膜和离子辐照技术在高温超导YBCO薄膜上制备Josephson结的方法.首先用在YBCO薄膜甩上一层800nm左右的光刻胶(PMMA),继而在光刻胶上用直流磁控溅射的方法镀上一层大约300nm左右的Cr膜,利用紫外曝光和离子刻蚀的方法在YBCO薄膜上形成覆盖有Cr膜的微桥,然后,利用聚焦离子束系统(FIB)在微桥上刻出一个50nm左右的狭缝,最后利用120keV的H2 对狭缝内的材料进行辐照,从而使狭缝部分的材料超导电性减弱,形成类似SNS型的Josephson结.     

碳离子辐照对人肺癌细胞A549细胞周期进程的影响

选取对数生长期人肺癌细胞A549接受0—6.0 Gy 碳离子照射， 用克隆形成法检测细胞的存活率； 并于照射后12和24 h收集细胞， 用流式细胞术检测细胞周期各时相的细胞百分比， 观察不同剂量碳离子辐照对A549细胞周期进程的影响。 结果显示: 0—6.0 Gy 碳离子照射后细胞存活率显著下降； 照射后12 h细胞发生G0/G1期阻滞， 而照射后24 h， 1.0 Gy 照射组细胞在G0/G1期阻滞， 2.0—6.0 Gy 照射组细胞在G2/M期阻滞。 上述结果表明， 在A549细胞接受碳离子照射后的12 和24 h内， 1.0 Gy 照射可持续激活细胞G1期检查点， 而2.0—6.0 Gy 碳离子照射后其细胞周期进程是随时间变化的。 To investigate the effects of cell cycle progression of A549 cell induced by 12C6+ ion irradiation at different doses, the survival fractions of the A549 cells were determined by colony forming assay; cell cycles were analyzed by FACS at 12 h or 24 h after irradiation. The results showed that the percentage of survival in the A549 cells decreased with irradiation doses. Compared with control group， the percentage of the cells in G0/G1 phase significantly increased at 12 h after irradiation with different doses of 12C6+ ions. However， at 24 h after irradiation the percentage of the cells in G0/G1 phase significantly increased with 1.0 Gy 12C6+ ions， while the cells showed increasing percentage in G2/M phase with 2.0, 4.0 or 6.0 Gy 12C6+ ions. The results suggested that G1 cell cycle checkpoint was activated in 12—24 h after irradiation with 1.0 Gy 12C6+ ions， but after irradiation with 2.0—6.0 Gy 12C6+ ions， the cell cycle progression of the A549 cells changed with time.     

不同能量的高电荷态Ar12+离子辐照对Au纳米颗粒尺寸的影响

报道了在兰州重离子加速器国家实验室电子回旋共振离子源原子物理实验平台上,在室温（293.15K）条件下,用固定剂量（4.3×10¹¹/cm²）的高电荷态⁴⁰Ar¹²⁺离子,辐照沉积在厚度为300nm的金膜表面上、平均直径约为35.3nm的Au纳米颗粒,使其大小发生改变的实验结果.实验中,通过改变入射离子的引出电压,选择不同的能量,利用原子力显微镜（AFM）对辐照前后颗粒的形态和大小进行表征,系统地研究了辐照后Au纳米颗 关键词： 纳米颗粒 高电荷态离子 离子辐照 临界能量     

离子辐照引起的金属／绝缘体界面混合与相变研究

载能离子穿过固体界面引起界面原子迁移使界面原子混合和物质成分变化，从而导致界面发生材料相变。简要介绍了载能离子辐照引起金属／绝缘体界面混合效应及相变现象的主要实验研究进展、低能离子和高能离子辐照引起金属／绝缘体界面现象差异，并对离子辐照引起界面混合及相变的机制进行了初步探讨。When penetrating an interface between two kind of solids, energetic ions can induce atomic diffusion at both sides of the interface and then result in intermixing, atom re-distribution or composition change, as well as phase transformation. Main progress on the study of intermixing and phase change at metal/insulator interface induced by energetic ion irradiations, the difference of phenomena occurred at metal/insulator interfaces induced by high-and low-energy ions were briefly reviewed. Furthermore, the possible mechanisms related to intermixing and phase change at metal/insulator interface produced by energetic ion irradiations were also discussed in short words.     

Formation,Dynamics, and Characterization of Nanostructures by Ion Beam Irradiation

Ion beam irradiation is a potential tool for phase formation and material modification as a non-equilibrium technique. Localized rise in temperature and ultra fast (～10^?12 s) dissipations of impinging energy make it an attractive tool for metastable phase formation. As a matter of fact, a major component of materials science is dominated by ion beam methods, either for synthesis of materials or for its characterization. The synthesis of nanostructures, and their modification by ion beam technique will be discussed in this review article. Formation of nanostructures using ion beam technique will be discussed first. Depending on species (e.g., mass and charge state) and energy range, there are various modes for an energetic ion to dissipate its energy. The role of the electron will also be covered in this article as a basic principle of its interaction with matter, which is same as for an ion. By using a simple reactive ion beam or electron induced deposition, a secondary phase can be nucleated by ion beam mixing techniques, either by using inert gas irradiation or reactive gas implantation on any desired substrate. Nucleation of secondary phase can also be executed by electron irradiation and direct implantation of either negative or positive ions. Post implantation annealing processes are required for the complete growth of clusters formed in most of these ion irradiation techniques. Implantation processes being inherently a non-equilibrium technique, defects always have a role to play in phase formation, amorphization, and beyond (blister formation). When implanted with large energy, even electrons, one of the lightest charged particles, also manifest these properties. Electronic and nuclear energy losses of the impinging charged particle play a crucial role in material modification. Doping a nanocluster, however, is still a controversial topic. Some light will be shed on this topic with a discussion of focused ion beam.     

离子束辐照的碳纳米管及其物性研究

离子束辐照通常被认为导致材料产生缺陷, 形成无序结构, 从而破坏材料的性能。 但是, 最近利用离子束辐照碳纳米管的实验显示离子束辐照碳纳米管形成无定形的过程不能用传统的离子束辐照材料的机制来解释, 离子束辐照可导致碳纳米管形成一些自组装结构, 如无定形碳纳米结和碳纳米管连接结等。 研究还发现离子束辐照的碳纳米管薄膜在导电性和场发射性能方面都能得到明显的增强。 Ion beam irradiation is usually thought to induce defects and disordered structures in materials and then to destroy the properties of the materials. However, our recent experiments about the ion beam irradiation on carbon nanotubes(CNTs) indicate that the ion beam modification mechanism of CNTs is completely different from traditional one of bulk materials, and ion beam irradiation can lead to self organized structures in CNTs, such as amorphous junctions and CNT junctions. Moreover, the irradiated CNTs exhibit a improved conductivity and an enhanced field emission.     

Synthesis and Characterization of Some Carbon Based Nanostructures

Carbon thin films were synthesized using the original Thermionic Vacuum Arc (TVA) method. Mechanical properties were investigated using Micro Materials NanoTest 500 instrument using a NT Berkovich indenter. XPS provides a quantitative analysis of the surface composition and X‐ray generated Auger electron spectroscopy (XAES) performed by Thermoelectron ESCALAB 250 revealed information about the sp³:sp² ratio of the carbon bondings. Structure and morphology was studied by Transmission Electron Microscope CM120ST, providing information on the grain size distribution of the crystalline diamond structures (© 2011 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Carbon Nanostructures

An overview of the various carbon structures with characteristic sizes in the nanoscale region is presented, with special attention devoted to the structures and properties of ‘nanodiamond’ and carbon nanotubes. The term ‘nanodiamond’ is used broadly for a variety of diamond-based materials at the nanoscale ranging from single diamond clusters to bulk nanocrystalline films. Only selected properties of carbon nanotubes are discussed, with an aim to summarize the most recent discoveries. Current and potential applications of carbon nanostructures are critically analyzed.     

Carbon Nanostructures in Lithium Ion Batteries: Past,Present, and Future

Advent of nanotechnology has generated huge interest in application of carbon-based nanomaterials as a possible replacement for conventionally used graphite as anode of Li-ion batteries. Future Li-ion batteries demand high capacity, energy, power, and better safety, while graphite falls short of fulfilling all these necessities. Inspired by high conductivity, flexibility, surface area, and Li-ion insertion ability, a number of nano carbon materials, individually or as a composite, have been studied in detail to identify the best suitable material for next-generation energy storage devices. Many of these nano-C-based structures hold good promise, although issues like density of nanomaterials and scalability are yet to be addressed with confidence. This article aims to summarize the major research directions of nano-C materials in anodic application of Li-ion batteries and proposes possible future research directions in this widely studied field.     

Electron Transport in GaAs Nanostructures under Irradiation

The results of theoretical and experimental investigations into the n-GaAs electrophysical characteristics under irradiation are reported.     

离子辐照单晶Si损伤效应的研究

回顾了低能离子注入单晶Si经由核弹性碰撞引起的损伤特征及其常规的研究方法,介绍了快重离子辐照单晶Si经由电子能损引起的损伤特点及研究现状,并对该领域的研究作了展望. The radiation damage in silicon induced by low energy ion implantation was briefly reviewed together with a short introduction to the common techniques in the area. The damage characteristics of swift heavy ion irradiation in silicon and its investigations were introduced with emphasis on the effects induced by processes of electronic energy losses. It is shown that swift heavy ion can induce defects far beyond the projected range and up to 28 MeV/μm the electronic energy ...     

Modification of Zinc-Implanted Silicon by Swift Xenon Ion Irradiation

50 keV ⁶⁴Zn⁺ ions to a dose of 5 × 10¹⁶ cm^–2 are implanted into substrates of single-crystal n-type silicon. Then the samples are irradiated at room temperature with 167 MeV ¹³²Xe²⁶⁺ ions with a fluence ranging from 1 ×10¹² up to 5 × 10¹⁴ cm^–2. Changes in the structure and properties on the sample surface and in its body are studied by scanning electron microscopy, energy dispersive microanalysis, atomic force microscopy, time-of-flight secondary ion mass spectrometry, and photoluminescence.     

碳离子辐射诱导秀丽隐杆线虫生殖细胞凋亡研究

重离子辐射具有独特的深度剂量分布和较高的相对生物学效应,被认为是理想的放疗手段。重离子的生物学效应在径迹形成过程中由多个物理参量共同决定,而这些物理参量和离子入射深度紧密相关,因此明确离子不同入射深度的生物学效应对重离子肿瘤放疗方案的设计和优化有着重要的理论和应用价值。使用兰州重离子研究装置HIRFL-CSRe 终端的碳离子束作为辐射源,以活体模式动物线虫作为实验对象,以线虫生殖细胞的凋亡水平作为生物学检测终点,研究了10 和20 Gy 碳离子辐射在辐射的入口、坪区和峰区的当代生物学效应和对后代个体基因组不稳定性的影响。结果表明:10 和20 Gy 碳离子辐射在三个不同的辐照区域内均显著增加了辐射当代的线虫生殖腺细胞的凋亡水平,并表现出一定的辐射区域和辐射剂量依赖性。同时,辐射诱导的后代个体基因组不稳定性也表现出一定的辐射区域和辐射剂量相关性。Heavy ion irradiation is a perfect means in radio-therapy due to its special depth dose distribution and high relative biological effects. The biological effects of heavy ion irradiation are determined by some major physical parameters, and vary along the tracks of heavy ions. Therefore, it is very significant for the tumor radio-therapy to investigate the biological effects along whole range of heavy ion radiation. In the present study, Caenorhabditis elegans, a model in vivo, was irradiated by carbon ion beams from HCRFL-CSRe, The level of germ cell apoptosis of worms was used as a checking endpoint for DNA damage, the effects of carbon irradiation located in the entrance, plateau and peak regions on the genomic instability of the irradiated worm and their progeny were detected. The results showed that the 10 and 20 Gy of carbon ion radiations led to the increased germ cell apoptosis in irradiated worms and these effects depend on the worm location along the range of carbon ions and the irradiation dosage. The results also suggested that heavy ion irradiation induced the up-regulated genomic instability in their progeny, and might be related to both the irradiation dose and the irradiated location.