Fe/Nb多层膜中离子辐照效应研究(英文)

采用磁控溅射技术在Si衬底上沉积Si/[Fe(10 nm)/Nb(4 nm)/Fe(4 nm)/Nb(4 nm)]2/ [Fe(4nm)/Nb(4 nm)]4多层膜。用2 MeV的Xe离子在室温下辐照多层膜。采用俄歇深度剖析、X射线衍射和振动样品磁强计分析辐照引起的多层膜元素分布、结构及磁性变化。AES深度剖析谱显示当辐照注量达到1 .0×1014ions/cm2时,多层膜界面两侧元素开始混合;当辐照注量达到2 .0×1016ions/cm2时,多层膜层状结构消失,Fe层与Nb层几乎完全混合。XRD谱显示,当辐照注量达到1 .0×1014ions/cm2时, Nb的衍射峰和Fe的各衍射峰的峰位相对于标准卡片向小角方向偏移,这说明辐照引起Nb基和Fe基FeNb固溶体相的形成;当辐照注量大于1 .0×1015ions/cm2时,辐照引起非晶相的出现。VSM测试显示,多层膜的磁性随着结构的变化而变化。在此实验基础上,对离子辐照引起界面混合现象的机理进行了探讨。

GeV能量的Fe离子在C_(60)薄膜中的辐照效应研究

利用傅立叶转换红外光谱和Raman谱仪分析了0.98GeV的Fe离子在电子能损Se为3.5keV/nm时,不同辐照剂量(5×1010—8×1013ions/cm2)下,在C60薄膜中引起的辐照损伤效应。分析表明,Fe离子辐照引起了C60分子的聚合与损伤。在辐照剂量达到一中间值1×1012ions/cm2,C60分子的损伤得到部分恢复,归因于电子激发引起的退火效应。通过对Raman数据的拟合分析,演绎出Fe离子辐照在C60材料中形成的潜径迹截面或引起损伤的截面约为1.32×10-14cm2。

1.23GeV Fe离子在C_(60)薄膜中形成潜径迹的Raman谱分析

用能量为1.23GeV的快Fe离子辐照了多层堆叠的C60薄膜。用Raman散射技术分析了快Fe离子在C60薄膜中由强电子激发引起的效应,主要包括辐照引起C60分子的聚合及其高温、高压相(HTHP)的形成,和在髙电子能损下C60晶体点阵位置上的C60分子向非晶碳的转变。由此演绎出了快Fe离子在C60薄膜中的损伤截面或潜径迹截面σ和潜径迹的半径Re,及其随沉积在电子系统中的能量密度的变化而变化的规律。

22MeV/u的Fe离子在PET膜中引起的辐照效应研究

用能量为22MeV/u的Fe离子在室温和真空条件下辐照了多层堆叠的半晶质聚酯膜,采用傅里叶转换红外吸收光谱、紫外/可见吸收光谱和X射线衍射技术分析测量了辐照后聚酯膜的微观结构所发生的变化,详细研究了分子结构的变化和非晶化转变与离子剂量、离子在样品中的平均电子能损以及吸收剂量的依赖关系.分析结果表明:辐照导致化学键的断裂、新化学键的形成和非晶化转变.非晶化效应和化学键的断裂随离子剂量和电子能损的增加而增大,但变化的总量仅依赖于总的吸收剂量,表明在所涉及的能损范围里,辐照产生的变化与辐照离子的种类和能量没有直接的关系,而只决定于材料对辐照离子能量的吸收程度.

~(40)Ca+~(58)Fe,~(58)Ni反应中的径向膨胀流研究

利用同位旋相关的Boltzmann Langevin方程研究了40 Ca + 5 8Fe和40 Ca +5 8Ni两个反应系统在 53 ,1 0 0 ,1 50和 2 0 0MeV/u入射能量下对心碰撞的径向膨胀流 .发现对于丰中子系统40 Ca + 5 8Fe的径向膨胀流系统性地小于稳定系统40 Ca+ 5 8Ni的径向膨胀流 .在假定轰击能量与反应体系的压缩密度呈抛物线关系时 ,能够解释入射能量和径向膨胀流之间呈现的直线关系 .提取了出现径向膨胀流的轰击能量阈值 ,发现对丰中子系统40 Ca + 5 8Fe得到的能量阈值小于稳定系统40 Ca+ 5 8Ni所得到的能量阈值

Modification of Fe/Cu Multilayers under 2-MeV Xe20+ Irradiation

Multilayers with a structure of Si/[Fe(10 nm)/CU(10 nm)](5) were deposited on Si(100) substrates and then irradiated at room temperature by using 2-MeV Xe20+. The modifications of the multilayers were characterized using a depth profile analysis of the Auger electron spectroscopy (AES) data and the evolution of crystallite structures of the multilayers were analyzed by using X-ray diffraction (XRD). The AES depth profiles indicated that de-mixing of the Fe and the Cu layers was observed at low ion fluences, but inter-mixing of the Fe and the Cu layers was found at high ion fluences and destroyed the layered structure of the multilayers. The obtained XRD patterns showed that, after irradiation by 2-MeV Xe20+ at; 2 x 10(16) ions/cm(2), the peaks of the multilayers related to a Cu-based fee solid solution and an Fe-based bee solid solution phase became visible, which implied that the inter-mixing at the Fe/Cu interface resulted in the formation of new phases. A possible mechanism of modification in the Fe/Cu multilayers induced by ion irradiation is briefly discussed.

Projected shell model description for high-spin states in neutron-rich Fe isotopes

A systematic study of neutron-rich even-even Fe isotopes with a neutron number from 32 to 42 is carried out by using the projected shell model. Calculations are performed up to the spin I=20 state. Irregularities found in the yrast spectra and in B (E2) values are discussed in terms of neutron excitations to the high-j orbital g(9/2). Furthermore, the neutron two-quasiparticle structure of a low-K negative-parity band and the proton two-quasiparticle structure of a high-K positive-parity band are predicted to exist near the yrast region. Our study reveals a soft nature for the ground state of N approximate to 40 isotopes and emphasizes the important role of the neutron g(9/2) orbital in determining the structure properties for both low- and high-spin states in these nuclei.

Modification of Fe/Cu multilayers under 400 keV Xe20+ irradiation

Two kinds of Fe/Cu multilayers with different modulation wavelength were deposited on cleaved Si(100) substrates and then irradiated at room temperature using 400 keV Xe20+ in a wide range of irradiation fluences. As a comparison, thermal annealing at 300-900 degrees C was also carried out in vacuum. Then the samples were analyzed by XRD and the evolution of crystallite structures induced by irradiation was investigated. The obtained XRD patterns showed that, with increase of the irradiation fluence, the peaks of Fe became weaker, the peaks related to Cu-based fcc solid solution and Fe-based bcc solid solution phase became visible and the former became strong gradually. This implied that the intermixing at the Fe/Cu interface induced by ion irradiation resulted in the formation of the new phases which could not be achieved by thermal annealing. The possible intermixing mechanism of Fe/Cu multilayers induced by energetic ion irradiation was briefly discussed.

Melting of Au and Al in nanometer Fe/Au and Fe/Al multilayers under swift heavy ions: A thermal spike study

Knowing that Fe is sensitive to swift heavy ion irradiations whereas Au and Al are not, the behavior of nanometric metallic multilayer systems, like [Fe(3 nm)/Au(x)](y) and [Fe(3 nm)/Al(x)](y) with x ranging between 1 and 10 mn, were studied within the inelastic thermal spike model. In addition to the usual cylindrical geometry of energy dissipation perpendicular to the ion projectile direction, the heat transport along the ion path was implemented in the electronic and atomic sub-systems. The simulations were performed using three different values of linear energy transfer corresponding to 3 MeV/u of Pb-208, Xe-132 and Kr-84 ions. For the Fe/Au system, evidence of appearance of a molten phase was found in the entire Au layer, provided the Au thickness is less than 7 nm and 3 nm for Pb and Xe ions, respectively. For the Fe/Al(x) system irradiated with Pb ions, the Al layers with a thickness less than 4 nm melt along the entire ion track. Surprisingly, the Fe layer does not melt if the Al thickness is larger than 2 nm, although the deposited energy surpasses the electronic stopping power threshold of track formation in Fe. For Kr ions melting does not occur in any of the multilayer systems.

Color center formation in silica glass induced by high energy Fe and Xe ions

Silica glass samples were implanted with 1.157 GeV Fe-56 and 1.755 GeV Xe-136 ions to fluences range from 1 x 10(11) to 3.8 x 10(12) ions/cm(2). Virgin and irradiated samples were investigated by ultraviolet (UV) absorption from 3 to 6.4 eV and photoluminescence (PL) spectroscopy. The UV absorption investigation reveals the presence of various color centers (E' center, non-bridging oxygen hole center (NBOHC) and ODC(II)) appearing in the irradiated samples. It is found that the concentration of all color centers increase with the increase of fluence and tend to saturation at high fluence. Furthermore the concentration of E' center and that of NBOHC is approximately equal and both scale better with the energy deposition through processes of electronic stopping, indicating that E' center and NBOHC are mainly produced simultaneously from the scission of strained Si-O-Si bond by electronic excitation effects in heavy ion irradiated silica glass. The PL measurement shows three emissions peaked at about 4.28 eV (alpha band), 3.2 eV (beta band) and 2.67 eV (gamma band) when excited at 5 eV. The intensities of alpha and gamma bands increase with the increase of fluence and tend to saturation at high fluence. The intensity of beta band is at its maximum in virgin silica glass and it is reduced on increasing the ions fluence. It is further confirmed that nuclear energy loss processes determine the production of alpha and gamma bands and electronic energy loss processes determine the bleaching of beta band in heavy ion irradiated silica glass. (c) 2009 Elsevier B.V. All rights reserved.